Method for Automatically Detecting Meaning and Measuring the Univocality of Text

ABSTRACT

The invention relates to a method for automatically detecting meaning patterns in a text using a plurality of input words, in particular a text with at least one sentence, comprising a database system containing words of a language, a plurality of defined categories of meaning in order to describe the properties of the words, and meaning signals for all the words stored in the database, wherein a meaning signal is a clear numerical characterization of the meaning of the words using the categories of meaning.

1. GENERAL POINTS 1.1 Summary

The claimed method of the computer-implemented invention “meaning-checking” (literally translated from German: “right-meaning-checking”) is: for each sentence of a text of a high-level natural language, to automatically, deterministically determine whether it is univocally formulated, by automatically calculating whether for each word that frames the sentence—computationally—only 1 single, relevant meaning of the word exists in the context and what this meaning is.

The meanings and coupled associations of all relevant words of the high-level natural language in which the sentence is written are stored in special pre-generated, standardized, numeric fields—so-called meaning-signals—and can be retrieved automatically.

In the invention these are automatically, arithmetically combined and comparatively analyzed—controlled only by the input sentence and its context per se—in such a way that as a result of the process either a formulation error is reported—if the sentence is not univocal—or each word is permanently linked to the single, associated meaning-signal which is valid for the word in this context.

This corresponds to the task of extracting information items from the sentence that are not explicitly, but normally only implicitly, present in it.

This implicit information of the sentence, which can be calculated out of the context by the invention, is based on the method according to the invention of the arithmetic and logical combination of the meaning-signals of the words present in the sentence, controlled solely by the special arrangement and morphology of the words in the sentence itself.

Note on Terminology:

Special technical vocabulary and invention specific, novel terms (e.g. meaning-signal, complementary or word ligature), are listed in Table 4. Standard technical terms from linguistics and computational linguistics are listed in Table 7.

1.2 Underlying Procedure

1.2.1 A method for automatically detecting meaning-patterns in a text using a plurality of input words, in particular a text with at least one sentence, comprising a database system containing words of a language, (line 1 in FIG. 3.1), a plurality of pre-defined categories of meaning in order to describe the properties of the words (columns 1-4 in FIG. 3-1, see FIG. 3.1 and explanations thereof in section 3.2), and meaning-signals for all the words stored in the database, wherein a meaning-signal is a univocal numerical characterization of the meaning of the words using the categories of meaning, and wherein at least the following steps are carried out:

-   a) reading of the text with input words into a device for data     processing, -   b) comparison of all input words with the words in the database     system, -   c) assignment of at least one meaning-signal to each of the input     words, wherein in the case of homonyms two or more meaning-signals     are assigned; -   d) in the event that the assignment of the meaning-signals to the     input words is univocal, the meaning-pattern identification is     complete, -   e) in the event that more than one meaning-signal could be assigned     to an input word, the relevant meaning-signals are compared with one     another in an exclusively context-controlled manner, wherein -   f) on the basis of the combination of the meaning-signals of the     input words among one another, it is determined whether a     contradiction or a match—particularly in the case of homonyms—is     present in the meaning of the input word with respect to the     context; -   g) meaning-signal combinations that lead to contradictions are     rejected (see FIG. 3.2 and related explanations in section 3.3),     meaning-signal combinations for matches are automatically     numerically evaluated in accordance with the degree of matching     (meaning modulation) based on a pre-defined relevance criterion (see     section 3.3) and recorded, -   h) automatic compilation of all input words resulting from the     steps d) and g) are output as the meaning-pattern or the numeric     meaning intersection matrix (FIG. 3.2) of the text, in particular of     the sentence. -   i) in the case of text where words with homophones are present, e.g.     from speech recognition and with appropriate triggering, including     checking the degree of meaning-signal correspondence, but also     morphological-syntactic compatibility of the word that is present     and its further homophonous spelling in relation to the context and     possibly automatic replacement or error warning in case of     insufficient differentiation among the meaning-signals of the words     of an identical homophone group in the context of the sentence under     test.

1.2.2 Problem Solved

“Meaning-checking” solves the technical problem in the automatic processing of texts that, in particular in the case of words with multiple meanings (=homonyms), is not explicitly present, in which of its meanings the homonym has actually been used in the text by the author of the sentence.

In spoken texts “meaning-checking” solves the same problem as for homonyms also for homophones. For homophones, the spelling of the word used is not determined when hearing a text.

Examples of homophonous words: Lehre-Leere (teaching—empty); or DAX-Dachs (DAX—badger); also, especially in German, in upper and lower case (e.g. wagen (be brave)-Wagen (car, vehicle); wegen (because of)-Wegen (ways, dative/plural of way);

in English, for example, to-two-too; or knew-new-gnu.

But also word ligatures (not compounds): e.g. “an die” (to the)-“Andy”;

or for example in Spanish “del fin” (i.e “from the end”)-“delfin” (dolphin).

The number of homophonous words (not counting common word ligatures) is e.g.: in German about 8,000 words, in English about 15,000 words, in French 20,000 words, in Japanese approx. 30,000 words).

This information of a sentence which is not explicit, e.g. with respect to the homonyms and homophones—but which is implicitly present in any univocal sentence of a natural language due to the combination of the words used themselves, in sentence and context—has up to now only been possible to be determined by human beings who master the language in which the sentence was created (be it phonetically or alphanumerically).

Homonyms and homophones belong to the most frequently used words in all languages. E.g. in German, of the 2000 most frequently used words about 80% are homonyms and approx. 15% homophones. In other high-level languages these values are sometimes much larger.

If one wants e.g. to discern the meaning of each word of a sentence in a completely unknown language, for each word of the sentence one must look up its meanings in its basic form—e.g. by means of a dictionary—and then—in the unknown language—determine which of the meanings was likely intended by the author of the sentence in the context of the other words of the sentence.

This is all the more difficult the more homonyms the sentence contains.

In the case of sentences with 5 or 8 words it is already common for hundreds, or even thousands, of basic possible combinations of the meaning of the words of a sentence to exist, although only one of the possible combinations is correct in the context. See for example in FIG. 2 the sentences 2.1.A1 and 2.1.A2.

In sentence 2.1.A2 after the application of the invention, the meaning of each word is identified and can be recognized by superscripts on the respective word. (See individual meanings in the box to the right) This sentence from FIG. 2 is univocal, although nearly 2 million basic possible meaning combinations of the meanings of its words exist for it. Refer to the information given in the fields J4-J6, and J15-J17 in FIG. 2. More detailed information on other meanings of the homonyms of this example is given in Table 1.

This problem—to determine the basic form, the possible semantic variants, and to calculate the correct meaning combination of a word in any given sentence and context—for all words stored in the databases linked to the invention with meaning-signals, is solved automatically by the invention.

And in fact this is done solely by automatic analysis and numerical comparison of the meaning-signals of the input text (sentence+sentence context) itself and without needing to analyze any other text databases, corpora, lexica etc.; neither statistically, nor by graph-based methods (e.g. calculation of edge lengths in Euclidean vector spaces), nor by means of artificial neural networks etc.

Here it is important to speak about meaning-signals because the selected structure and arithmetics for computational treatment of meaning-signals corresponds to the computer-based treatment of numeric patterns, in contrast to a rather neurological term like “associations”.

Meaning-signals do represent associations on a numerical way, but they are not themselves associations.

It is the analogy of the process of mutual modulation of meaning-signals from the field of communications technology, as well as the existence of electrical “currents” in the brain during the processing of associations when language is perceived by human beings, which recommend the use of the new expression “meaning-signals”.

1.3 Technical Applications/Comparison to the Prior Art

A direct, practical application of the invention, beyond meaning-checking, are e.g.:

-   -   High quality automatic machine translation systems, because:     -   Firstly, only univocal sentences can be translated correctly.         Secondly, an univocal sentence can only be assigned correct         translations, if the—only—relevant meaning of each individual         word of the sentence in the context is known. The perceived         state-of-the-art based on well-known products—regardless of         whether they are free of charge or not—=50% incorrect         translations, e.g. in the case of statistical machine         translation engines. The database to be searched in the         invention is nevertheless smaller by a factor of 500 . . . 1000         than those based on conventional statistics machine translation         systems, while increasing the translation quality to better than         95%. (cf. Tables 5+6)     -   The knowledge of the relevant unique meaning of each word in the         context allows, among other things, a novel, automatic, semantic         indexing of text databases according to meaning, which then         allows very much more accurate search results from search         engines (a factor of 99% to 99.99% fewer irrelevant hits), than         the prior art. Perceived state-of-the-art technology based on         well-known products=if the search term is a homonym, the hits         for all meanings of the word are displayed and not only those         for the single intended meaning.     -   In addition, for speech recognition or human-machine dialogs         this knowledge of the relevant unique meaning of each word in         the context allows a precise—meaning-related—recognition and         further processing of the input—also in the form of         automatically generated input-related, rationally intelligible,         interactive dialogs—which have not existed up to now.     -   Perceived state-of-the-art technology based on well-known         products=100% erroneous interpretation of homophones, and no         reliable detection of words that are important for logical         inferences. See also example 2.2 sentences 2.2.B1 and 2.2.B2.

1.4 Summary of Description

The computer-implemented procedure of the invention may be compared in a purely formal way to that of a spell-checker. The abstracted flow diagram of the (new) meaning-checking (B) is very similar to that of the (known) automatic spell-checker (A). FIG. 1

(B)—the invention—is based on a novel numerical type of processing that allows the relevance of all possible associations of a word to its context, stored in meaning-signals, to be automatically calculated.

Meaning-signals are the data underlying each individual word and each of its different meanings. Meaning-signals are fixed and are multi-dimensional numerical fields which can be compared with each other numerically and logically. In the invention meaning-signals are defined for all relevant words of a high-level language and are automatically retrievable—FIG. 4.7.

A meaning-signal of a word becomes “valid” in the context (FIG. 1, Box in line 3, right), if it has only one meaning-signal—either because it has only a single meaning, or because the meaning-signal of at least one other word in the context has multiple matches with it, in fact significantly more, than other words in the context. Words which “validate” each other in terms of their meaning are called “complementaries” in the context of the invention. (Detailed definition is given at the beginning of Section 2)

Words of any sentence can have more than 1 association in the context, because:

In all languages there are tens of thousands of words (e.g. German about 35,000, in English about 50,000), which have exactly the same spelling but several different meanings (called homonyms): E.g. in German Lauf [13 meanings], Zug [43], Geschoss [4], anziehen [12].

Homonyms are particularly frequently used in all languages in comparison to non-homonyms.

Also, sentence particles are usually homonyms which have multiple, usually position-dependent meanings and syntactic functions, depending on the word or phrase to which they are assigned.

For sentence particles alone there are thus a total of approximately 5,300 homonyms, if adverbs are included (they are non-inflecting words in terms of their function).

Almost every sentence of text from a natural language contains homonyms. The purely lexical⁷ analysis options of the prior art of EDP—in practice equal to a Gutenberg typecase with 255 ASCII characters—are therefore seriously inadequate for the task of processing words by their meaning in a text.

This applies to all spoken, high-level natural languages.

The meaning which is assigned to a homonym by the author of a text is determined by the context in which the homonym occurs, it cannot be obtained explicitly from the text itself.

Only after the application of the meaning-checking (B) is it known (in FIG. 2 conversion of text 2.1.A1 into the indexed form 2.1.A2), whether and which meaning of each homonym has a relevant meaning in the sentence context.

This property of natural languages—that the univocal meaning of the words used with multiple meanings cannot be explicitly extracted from the text itself, but can only be associated implicitly to the context by language knowledge—internationally has no generally valid definition in linguistics.

Within the discipline of sentence semantics, this property is circumscribed in the broadest sense, using terms such as “equivocation⁷”, “homonymy⁷”, “ambiguity⁷” and “polysemy⁷”. In the prior art the terms “word-sense disambiguation” or “reduction of ambiguity” are commonly used. But it is formally, logically incorrect or very misleading, to say that a word can be “disambiguated” or that the “ambiguity of a sentence” can be reduced, because:

A word in a sentence or a sentence are univocal or they are not. This can only be eliminated by the author of the sentence and the context of the sentence.

That is, the non-univocality of a sentence can only

-   (a) be determined by a human being, or -   (b) calculated automatically with appropriate methods (the claimed     invention).

In the following text therefore the entire, new, claimed method that is capable, in spite of the “equivocation”, “homonymy”, “non-univocality” and “polysemy” ever-present in natural language, of calculating the number of meanings used of all words in a sentence and which ones, is given the following name: “Determination of the implicit meaning of a sentence, by calculating the complementary, associable, semantic relations between its words”.

In English, Abbreviated to:

SenSzCore—Sentence sense determination by computing of complementary, associative, semantical relationships.

Without meaning-checking, resp. without SenSzCore, it is not possible e.g. for speech recognition or translations to carry out really accurate, automatic, correct meaning-oriented work with texts themselves. Without meaning-checking blatant interpretation errors constantly occur in the automatic processing of meaning—as is the case with the application of the prior art.

Meaning-checking with SenSzCore is crucial to the automatic processing of texts with detection of the meaning of the words and represents the operational precondition for electronic sense processing (ESP⁴) of texts in high-level natural languages, in contrast to the prior art—Electronic Data Processing (EDP).

Statement on Translation Software or Speech Recognition Software from the Prior Art:

All applications which base the meaning of sentences on the analysis of words themselves—and not on their associations in the context and irrespective of how large the quantity of analyzed words is—can only find the correct meaning of the analyzed words in the context in approximately 50% of cases.

Proof:

Ca. 50% hit rate of e.g. standard commercial machine translation systems.

Cause:

The analysis of explicit—therefore purely lexical—data of the sentence existing in the form of 255 ASCII characters—e.g. by statistical methods with other similar sentences—cannot—per se—deliver any implicit information—because this is not inherently present in the alphanumeric character combinations, but in the mind of the reader of the text at the moment when he reads this text, assuming that he has sufficiently good language skills in the language in which the text is written.

In other words: the implicit information of the sentence is only monolingual⁷, and can only be recognized computationally using associations that are processable by computational means—similar to those in the brain of a reader of the text—between the words of the language in which the text is written.

Figuratively speaking the invention represents a novel method, which with the application of “associably digitized meaning” (meaning-signals) of words in their context allows computational processing, similarly to the way in which a CCD camera, by turning exposed light-sensitive areas into pixels, is a prerequisite for the computational based processing of images.

Nevertheless, meaning-signals are logically and structurally much more complex than the short numerical information of image pixels which result from a light-sensitive surface.

Further examples relating to this issue are given in the next section.

1.5 Function Principle and Comparison to the Prior Art

If in the context of a German sentence (e.g. “Wir werden die Preise anziehen.”—[We will increase the prices]), a person encounters words (here: Preise [prices]), for which for all semantic associations of its homonyms (here: anziehen [increase]) validate only one meaning in each case, then the sentence is univocal to a reader.

The subject matter of the invention is to implement this kind of decision—which in human beings occurs very rapidly and unconsciously—automatically and only by computational processing of the sentence itself, its context and its associated, invention-specific meaning-signals.

Especially in the case of translations or speech recognition, shortcomings in the automatic definition of the meanings of words quickly become clear:

Automatic machine translation systems according to the prior art will e.g. translate the German sentence:

“Ich nahm einen langen Zug aus der Zigarette.” (I took a long draw from the cigarette.)

completely wrongly, as:

“I took a long train from the cigarette”.

Or the sentence (Fig. 2.1.A1):

“Der Zug im Lauf verleiht dem Geschoss eine Drehung um seine Längsachse.” (The groove in the barrel makes the projectile rotate about its longitudinal axis.)

completely wrongly, as:

“The train in the course gives the floor a rotation about its longitudinal axis.” (FIG. 2 coordinate H8). See also the individual meanings of the words in Table 1.

Unless the sentence and its correct translation are available in the programs as a stored example, translation programs according to the prior art exhibit this type of serious error in approximately 50% of their translations.

To date, in the prior art only indirect methods of meaning assignment have been known in machine translation systems (e.g., U.S. Pat. No. 8,548,795, U.S. Pat. No. 8,260,605 B2, U.S. Pat. No. 8,190,423 B2). These try to determine the correct assignment of words in the context automatically, based on statistical or graph-based methods by analysis of large text corpora (collections of large quantities of text, e.g. translated EU minutes, with millions of sentences), or so-called “world knowledge databases”.

In the prior art it is not even attempted to directly detect the actual, associable meaning of the input text—per se.

In the prior art, to assign a correct translation (=indirect meaning acquisition), all that takes place is an attempt to find sentences or sentence fragments that match frequently with the input text of the one language in the other language—in parallel—and to assemble them together to form a reasonably readable translation. The result is demonstrably unpredictable regarding quality: only about 50% of the translated sentences by machine translation systems according to the prior art are semantically and grammatically correct. (See also the examples in Table 5).

According to the new method (B), FIG. 1, of “meaning-checking”, all relevant meanings of words of a language, including all their relevant inflected forms (variation of words according to grammatical rules, e.g. declension, plural formation etc.: the train, trains . . . go, went, gone, going, on the go . . . ) are numerically acquired and permanently stored in a computer-implemented database (e.g. FIG. 4.7) individually, so to speak, as digital meaning-signals.

The creation of the meaning-signals is a one-off manual operation that is carried out in advance. The resulting database, with about 50 million words in High German, corresponds roughly to the size of 20 large monolingual dictionaries, and is therefore approx. 1000× smaller than databases which are used e.g. in translation programs in the prior art.

By comparing the words in a sentence with one another, using all of their meaning-signals stored in the abovementioned database, it can be automatically calculated for all words what their correct meanings in the sentence context are in each case. For any given sentences and in any given context.

This represents a new, direct, deterministic procedure.

It allows for the use of pure arithmetics and requires no statistical or graph-based algorithms to compare the sentence, or parts of it, with large corpora in order to form statistical conclusions.

In the invention the sentence is not compared with other sentences—as in the prior art—but the meanings of its words with those of the other words of the sentence itself, and possibly with those of its immediate context. This is done numerically, at the level of words or word chains.

In the narrower sense what is performed with the invention is a local measurement—as with a digital measuring device by addition of digital signals from a signal source—in this case from a database—(for sample content, see Table 1) by retrieval of meaning-signals (FIG. 3.1) that are permanently assigned to specific words and all their correct inflected forms.

In the case of words with only one meaning, only a single, complete meaning-signal of the word and all its inflections is listed in the database. In the case of words with “n” meanings (homonyms), “n” and only “n” different meaning-signals of the individual word and all its inflections are listed in the database.

All meaning-signals of a word are—via its written form as text—retrievable from the database, regardless of the inflection in which it occurs. A meaning-signal exists in a standardized, alphanumeric, arithmetically evaluable, multi-dimensional form. (For components of the meaning-signals, see FIG. 3.1; for explanations see Section 3.2)

To determine the contextually correct meaning-signal of a homonym with “n” meanings within the context of a sentence, the “n” meaning-signals in all its categories are arithmetically added, in pairs, to those of all other meaning-signals of the words of the sentence (see FIG. 3.2 and FIG. 5). This happens as many times as there are different meaning combinations of all homonyms and words present in the sentence. Each meaning-signal of the homonym, modified by the arithmetic operation, is temporarily stored—for subsequent comparison. This is in matrix form, for example, as shown in FIG. 3.2.

If, following the arithmetic procedure of the invention a homonym can be found in the local context among the calculated results from the sentence, which is unchanged by any of the other words in the sentence in a relevant way in all its meaning-signals, then the sentence is not univocal and—in a manner similar to a spell checker—a message is displayed automatically to the user that no permissibly formulated text is present in the input sentence (FIG. 1, FIG. 4, FIG. 6). The invention therefore carries out, so to speak, an automatic “meaning-checking” of the sentence. (For comparison to a spelling check, see FIG. 1)

Meaning-signals can be permanently assigned not only to individual words, but also to predefined word chains (including so-called “idioms”, e.g. German “schwer auf Draht sein” (literally “to be heavy on the wire”)=“to be fit”). When the term “word” or “words” is used hereafter, all statements made also apply to word chains, which are shorter than the sentence itself in which they occur. If a word is contained in a word chain for which a separate meaning-signal exists, then for the arithmetic calculations the word chain is treated as a single word.

Non univocal sentences can be neither correctly translated nor correctly indexed; they are therefore useless for “electronic sense processing”=ESP.

For “intelligent” processing of language it is therefore crucial to have a procedure that can measure the univocality of sentences.

2. THEORETICAL BACKGROUND AND INVENTION Specific Terms

The invention is based on, among other things, the linguistic, language-independent fact that:

in sentences with homonyms—or their immediate context—at least one other word of the same high-level language must exist for each homonym, which renders one and only one meaning-signal of each homonym valid, so that the sentence receives a unique meaning in this particular high-level language.

These words—which “validate” one of the meaning-signals of a homonym in the context—are hereafter termed “meaning-complementaries”, or “complementaries”.

In linguistics the term “complement” is familiar from structural syntax and has a completely different function than the “meaning complement” newly defined here. Also, the German neuter form “das Komplementär” [Complement] is selected, to distinguish it from the term “der Komplementär” [general partner] from commercial law.

Meaning-complementaries numerically change the meaning-signal of a homonym in individual categories greater than zero. The greater the arithmetic change in the meaning-signal of a homonym by other words, the stronger is their complementarity in relation to each other.

In Telecommunications Terms:

If the “n” meaning-signals of a homonym in a sentence undergo no amplitude modulation in the amplitudes of its meaning-signal that are >0 due to its context, in all its meaning variants, then the sentence does not have a unique meaning/is not univocal.

Hereafter, the superposition of meaning-signals is referred to as “modulation”, as this best describes the process.

Each word can be a complementary for any number of other words. Therefore every word of a language must have its own meaning-signal, in order to be detected by the meaning-checking process with SenSzCore.

The meaning-signal structure in the invention is structured as a result of empirical trials, such that complementarity occurs in the same cases as those which a person of average education intuitively identifies when reading a sentence.

The meaning-signal structure in the definition and position of individual meaning categories is equal for all words (FIG. 3.1). Meaning-signals differ only in the values of their individual categories.

Meaning-signals can be thought of as multi-dimensional numerical fields.

Words with little meaning, such as: “thingamajig” (can mean almost anything) have values=0 in almost all individual meaning categories.

Abstract words, such as “heroism”, or words with many semantic facets, such as “apprentice”, have values greater than 0 in many positions. In compounds the meaning-signal of the word in many of its meanings can be framed to the greatest extent from the sum of the meaning-signals of its components.

E.g. the meaning-signal of the German word “Pferdewagen” (“horse-drawn carriage”) is the sum of the meaning-signal of “Pferd 1” (“horse 1”)<zool> and “Wagen 3”<2D Gefährt mit Roll_Rädern><kein eigen_Antrieb>(“carriage 3”<2D vehicle with wheels><no intrinsic_drive>).

This example is intended to clarify the essential difference between a meaning-signal and the definition of the word.

-   -   a meaning-signal is a numeric store of normalized associations.     -   a semantic definition, by contrast, is a chain of words which         can invoke associations in the brain when reading. See         comparisons in FIG. 3.1 . . . .

Currently the meaning-signals in the invention consist of 512 individual meaning categories and 15 basic signal groups (FIG. 3.1). These indicated figures are only an empirically determined, pragmatic value that produces good results in the new procedure when calculations from the invention are compared with the perceptions of human beings in relation to the uniqueness of sentences. But other values can also be used. Less than 50 individual categories and less than 3 basic signal groups generally lead to unusable results, however, that are roughly as poor as those of e.g. machine translation systems from the prior art.

For German, the invention has a database of approximately 50 million words (approx. 0.1% compared to the volume of words in statistical translation programs according to the prior art), which are composed of the inflected forms of approximately 1 million different words in their base form, which in turn consist of meaning-signals which can be formed from approximately 20,000 relevant basic meaning-signals of a high-level language.

This fine resolution corresponds to everyday business language usage—technical, commercial, scientific.

More restricted specialist language domains, such as gastronomy, could be described sufficiently well with as little as 1/10 of this volume of words. For good results in restricted ontologies⁷ however, the full set of all homonyms from general language and the restricted language domain must be included in the selection.

2.1 Structural Information on the SenSzCore Database

Words A, A′, . . . with equal meaning-signal but spelled differently from another word B are synonyms of B.

Words A, A′, . . . with different meaning-signal and spelt the same as another word B are homonyms of B.

Words A, A′, . . . with largely similar, but shorter meaning-signal than another word B may be hyponyms of B.

Words A, A′, . . . with largely similar, but longer meaning-signal than another word B may be hyponyms of B.

For each high-level language there are approximately 50,000 relevant synonym groups with on average approximately 8 synonyms.

The words of a high-level language which have no relevant synonyms are hereafter referred to as “singletons”.

100% synonyms are usually only variant spellings of a word (e.g. photo/foto). In the databases of the invention, words that have meaning-signals with an overlap of >85% relative to each other are treated as synonyms. The decision is however made manually—in advance—when the data are created, and following the rule: synonyms are words that in a sentence are interchangeable without changing the sentence meaning significantly.

Another important property of meaning-signals is that they are language invariant. From this it follows that: all of the words of equivalent synonym groups have the same meaning-signals in all languages.

The calculations of the “meaning-checking” on the basis of meaning-signals can therefore be performed irrespective of the source language.

Meaning-signals are additive in certain areas. Within a meaning-signal, multi-dimensional valence references between individual meaning categories are also possible and present (see constraint references (CR) in FIG. 3.1, Section 3.2).

2.2 Notes on Function and Terms Based on Examples EXAMPLE A1

German “Wir werden sie anziehen” (We will tighten/dress/attract . . . them):

In this case the sentence has a transitive meaning of the verb “anziehen”, for which the SenSzCore database contains 10 different, transitive meaning-signals.

Including (highly simplified representation)

Homonym Short Description Example anziehen1 = put on clothing, . . . (e.g. trousers) anziehen2 = increase interacting force, . . . (e.g. screw) anziehen3 = increase value, . . . (e.g. prices) anziehen4 = exert attractive field force, . . . (e.g. with magnet) anziehen5 = appear mentally attractive to s.o., (e.g. by words) anziehen6 = make data available, . . . (e.g. quotation) anziehen7 = retract, do not stretch . . . (e.g. leg) anziehen8 = exert indirect attraction force, . . . (e.g. tree stump with rope) . . .

In the example A1: “Wir werden sie anziehen” the addition of e.g. “Hose” (trousers) would create univocality:

“Wir werden die Hose anziehen”. (We will put on the trousers).

The meaning-signal of “trousers” carries values in multiple categories of meaning-signal that also match categories occupied by the meaning-signal of “anziehen1”: “put on clothing”.

The meaning-signal of “anziehen” in the meaning “put on clothing” is thus changed significantly by the presence of “Hose” (trousers) in the sentence. “Hose” (trousers) and “anziehen” (“put on”) are therefore complementaries in the sentence “Wir werden die Hose anziehen.” (We will put on the trousers.)

The meaning-signals of “trousers” and “put on” are each modulated significantly in 1 of their meaning possibilities. In all their other meanings they either do not modulate each other or do so to a considerably weaker degree.

Similarly, univocality of the sentence would be created with the other meaning-signals of “anziehen”, if one were to write:

“Wir werden die Preise anziehen.” (Preise=‘prices’) (=increase), or

“Wir werden die Beine anziehen” (Beine=‘legs’) (=bend), or

“Wir werden die Schraube anziehen” (Schraube=‘screw’) (=tighten) etc.

Each of the words added to example A1 modulates another meaning of “anziehen” as a complementary and automatically validates a single specific, different, correct measurement and therefore makes it automatically processable. The homonym is “validated” by the complementary.

For each sentence which contains “anziehen”—transitively—SenSzCore will respond to complementaries in a similar form. E.g. “Rock (skirt) 2<clothing>”, “Gehälter (salaries) <econ>”, “Arm <anat>”, “Dehnschraube (Expansion bolt) <mech>”, “Bremse (Brake) 3<mech>” etc., lead in just the same way to a correct, automatic calculation of the local, transitive meaning of “anziehen”, such as the complementaries already mentioned above in example A1.

If one were to write the above complementaries into a preceding sentence:

EXAMPLE A2

“Wir haben die Marktpreise sorgfältig geprüft. Wir werden sie anziehen” (We have carefully examined the market prices. We will increase them.), then the invention recognizes the relation between “sie” (them) from sentence 2 and “market prices” from sentence 1 and automatically calculates the meaning “erhöhen” (increase) of “anziehen” as the relevant one.

Hereafter we call this condition: “cross-sentential complementarity”. This occurs very frequently with “deictic⁷” references in the sentence.

The function of the invention also allows the automatic selection of the correct meaning of a homonym if several complementaries occur in the sentence:

EXAMPLE A3

“Er nimmt den Schraubenschlüssel aus der Hose and wird die Schraube anziehen.” (He takes out the wrench from the trousers and will tighten the screw.)

Here, “screw” and not “trousers” is the complementary of “tighten”. Due to the conjunction “and” the invention recognizes the subject “screw” in the second main clause, which constrains the search for complementaries to this second main clause.

If several homonyms are not sharply separated from each other syntactically (e.g. as would be the case with conjunctions), then essentially the same standard procedure is followed as when the sentence has only a single homonym. All meaning-signals of the words of the sentence are compared with all meaning-signals from all other words of syntactically definable sentence parts. Usually, the complementaries in this type of sentences only occur in close proximity to their homonyms—because otherwise, these sentences would be very difficult to understand. This is why in the invention, in the case of sequences of multiple homonyms, the distance between them in the sentence is included in the calculation. Usually, the subject-object relation can also be helpful in this approach.

If a homonym modulates with several other homonyms, then the meaning-signal of the other homonyms which they themselves most resemble is preferred. Hereafter we call this condition “multiple complementarity”. If at the end of the calculations there is more than one possibility with the same value, the meaning of the sentence is not unique and the “meaning-checking” automatically generates an error message.

For completeness, here is another example.

EXAMPLE A4

“Er ist am anziehen” (He is tightening/bending/increasing etc.), in which the intransitive⁷ meanings of “anziehen” must be used.

These are:

Homonym Short Description Example anziehen11 = exert a drive-dependent force, . . . (e.g. locomotives) anziehen12 = actively modify material structure, . . . (e.g. adhesive)

In this case the sentence A4 is inherently logically not univocal. In the invention, only suitable complementaries of the meaning-signal of drive-dependent objects such as “locomotive” for anziehen11 “The locomotive is being driven”, or chemically active materials such as “adhesive” for anziehen12 “The adhesive is setting”, lead to a correct meaning assignment. The use of e.g. “Hose” (trousers) in “Die Hose ist am anziehen”, on the other hand—in the absence of complementarity—leads to an error message from the “meaning-checking”.

This is because the word ‘trousers’ has in the meaning-signal no values in categories such as “can exert drive-dependent force” or “can actively modify material structure” which modulate ‘anziehen’ in the intransitive syntactic function.

2.3 Notes on the Function and Terms on the Basis of Examples with Translations from the Prior Art

A particularly impressive way to demonstrate the difficulty of automatic electronic sense processing “ESP” and the accurate, simple functioning of the invention is by using typical errors from well-known machine translation engines from the prior art.

First Some Observations on the Prior Art: (Table 2)

In B1 and B2 the most common use of “Zug” is obviously used in the translation: “train”. This is the typical result of a statistical approach to determining the “meaning”. In example B1, each of the 3 homonyms “train”, “running” and “floor” is even incorrectly detected in the meaning and therefore incorrectly translated.

In B1 the meaning “running” is used for “Lauf”, instead of the meaning “gun barrel”.

In B1 the meaning “floor” is used for “Geschoss”, i.e. the floor of a house and not the word “projectile”.

In B3 and B4 the meaning “bullet” is used for “Geschoss” instead of the floor of a house, “floor”.

By using “meaning-checking” in these 4 examples, only correct interpretations are obtained, because in each example sufficient complementaries are contained which determine the univocality of each sentence arithmetically:

In B1: the word “Geschoss” gives the meanings of “Zug” and “Lauf” a high priority in their “weapons-related” meanings, (Engl.: “groove” for “Zug” and “barrel” for “Feuerwaffen-Lauf”) and therefore produces—by using multiple complementarity—the correct translation into English by the invention: “In the groove of the barrel the projectile gets a rotation around his longitudinal axis.” See also FIG. 2 and Table 1.

In B2 “zigarette” (cigarette) gives priority to the “Zug” from “Lungenzug” (Engl.=“puff”), so that the correct translation into English is given by SenSzCore: “In the course of the last minute I took just one deep puff from the cigarette.”

In B3 “Gefahrenausgang” (emergency exit) and “Gebäude” (building) are the complementaries for “Geschoss” of a building (“floor”) and thus produce the correct translation into English by the invention: “The floor must have an emergency exit on the rear of the building.”

In B4 “Personen” (people) and “sperren” (lock) are the complementaries for “Geschoss” (floor) of a building. In the second clause the word “Sturm” (storm), due to its mobility and dimensional values, among others, gives the complementarity of the synonym group “heranziehen” (engl. “be approaching”) to the word group “im Anzug sein” (“be approaching”) in the meaning-signal and therefore produces the correct translation into English from SenSzCore: “The floor was barred for persons, because a storm was approaching.” It is important to note that a complementarity for “Anzug” (suit), in the sense of clothing, is not present in this sentence.

Important Note:

The quality of a translation is determined by, amongst other things, the fact that homonyms in the target language also find the correct complementaries of the other language in the sentence. This is also automatically ensured by the design and structure of the invention: By selecting the translations from synonym groups that are assigned to an identical meaning-signal in all languages, the meaning complementarity of the words is necessarily preserved after the translation.

To provide an overview of typical difficulties in the assignment of meaning in the prior art as compared to the invention, the most recent examples are summarized again in Table 3.

3. DETAILED DESCRIPTION OF THE INVENTION The Figures

3.1: Overview of the structure and content of meaning-signals

3.2: Typical value comparison matrix for the comparison of meaning-signals

4, 6: System overview of meaning-checking system

5: Flow diagram for calculating the meaning scores of words

-   -   (procedural box 4.11 in FIG. 4)         explain the basic components and the processes of the invention         in detail.

3.1 Explanation of the Processes in FIGS. 4+6:

By means of data input, e.g. using a display device or a speech recognition system and corresponding signal conversion, the processable text reaches the computer-implemented meaning-checking system (sections 4.5 to 4.13 in FIG. 4).

The invention can also be described in an abstract form as a:

“computer-implemented, context-sensitive signal transducer+measuring device”.

This means that in the invention, pure orthographic signals are converted into meaning-signals, by means of a measuring device, that

-   a) determines whether the text input is univocal and -   b) if yes, each string of letters without spaces is associated with     a correct meaning-signal—in relation to the context of the sentence.

The meaning-checking processes the text sentence by sentence.

The processing of single words is not provided, unless there are sentences of length=1_word which have a special semantic/syntactic function (e.g. interjections such as “Hello!”, “please!”; or impersonal verbs, e.g. in Romance languages: Spanish: “Llueve.”, Italian: “Piove.” . . . =“It's raining.”).

After the existence of all the words of the sentence has been checked in 4.5.1 against the data held in the EDP system 4.7 and is positive (i.e. all cases where the letter combination itself does not lead to exclusion, e.g. “haven” instead of “haben” or “haken”, etc.), a recursive, automatic operation is performed in which the syntactic function for each word in the sentence is determined. This process does not require the use of classical “parse trees”. Using the meaning-signals of particles and the subsequent words, in over 85% {own empirical evaluations of thousands of sentences} of practical cases it is possible to determine the syntactic function of each word, if no structural spelling errors are present (structural spelling error=incorrect letters).

If it is not possible to determine the syntactic function of each word (approximately 15% of cases=all words exist but their syntactic function cannot be uniquely identified), it is supported by the calculation of meaning-signals in individual word pairs whose syntactic function cannot be determined exclusively via their position in relation to each other.

This also already takes account of any syntactic spelling errors of words which, e.g. in German, allow both upper case and lower case spelling of a word, but which is not correct for the current sentence (e.g. “Wir Karren den Mist vom Hof.” (We cart [noun] the manure from the farm.”). Several recursive loops are possible between 4.5.1 and 4.5.2.

E.g. “Die liegen am Pool waren Besetzt.” (The lie at the pool were occupied.” . . . will require 2 passes. (The completely wrong, structurally correct spelling is of course already ruled out by 4.5.1).

It is important to note that, for sentences such as “Wir Karren den Mist vom Hof.” (lit: We cart [noun] the manure from the farm.), in contrast to SenSzCore, popular spell checkers from the prior art—as a result of their functional principle—cannot display an error . . . and in fact do not do so.

If there is no univocality in the syntax itself—i.e. where a word can be e.g. only a noun but is used with an adverb, e.g. “I want fast car.”, then automatic user dialogs 4.9 are invoked or at a higher level via the User Interaction Manager, FIG. 6 (7), which display the fundamental, syntactic ill-formedness of the sentence. The exclusion criteria are automatically displayed, but in this case no indication of correction options is given.

If the syntax of the sentence is univocal, then a meaning check 4.11 takes place according to the automatic process shown in FIG. 5.

This is supported by the EDP system 4.7 and appropriate databases, temporary storage facilities, and arithmetic calculation functions. (See also the explanations for FIGS. 3.1 and 3.2).

It is important to bear in mind that SenSzCore does not initially evaluate non-univocalities that are of a purely logical nature:

For example, the sentence “Meine alte Freundin hatte gestern Husten.” (“My old girlfriend had a cough yesterday.”): in terms of meaning-signals the sentence is univocal. Whether the “girlfriend” is old or is “a long-term friend,” remains a secret known only to the author of the sentence. This logical non-univocality is maintained in translations with SenSzCore, without leading to a semantic error in the target language. It is in fact, inter alia, a quality hallmark of any translation that logical content of the sentence is not changed unnecessarily in the target language.

With SenSzCore, after the completion of the calculations 4.11—if the sentence is univocal—the most common synonyms are also now available for all words. These are displayed to the user on request in the autotranslation 4.8. If the user e.g. has entered the sentence: “Ich nahm einen tiefen Zug aus der Zigarette” (“I took a deep draw from the cigarette”), he obtains from the autotranslation, 4.8 a sentence in which the inflecting homonyms are substituted with their most relevant synonyms from the database 4.7. In this case, the user obtains: “Ich nahm einen tiefen ‘Lungenzug’, aus der ‘Filterzigarette’.” (I took a deep draw from the filter cigarette.) This function is intended to show the user on request—in his own language—that the meaning he wanted to express has been correctly recognized by SenSzCore, by substituting semantically correct synonyms.

It is important to note once again the fundamental difference between the statements 4.4 (—before—meaning-checking) and 4.12 (—after—meaning-checking) in positions 1) and 2).

The invention has now transformed a text without any semantic information, e.g. 2.1.A1 into a text with semantic information 2.1.A2, which has been calculated solely from the comparison of the meaning-signals between the words of the sentence and which was not previously—explicitly—contained in the input sentence. See also further information in FIG. 2.

After the completion of the calculations an alternative representation can be computationally created for the sentence with coded values which correspond to the meaning-signals of the words (FIG. 4.13), including their syntactic and morphological information, which of course has also been determined by SenSzCore. This additional information can therefore be indexed in multiple ways. It is crucial that the mathematical univocity between meaning-signals and coded values of the indexing remains known in computational terms. The indexing is advantageously effected using the meaning-signal itself, but can also be supplemented or replaced by other user-specific codes, which retrieve the meaning-signal from linked data only on subsequent use.

A sentence coded in such a way can now be advantageously further processed in the listed functions 4.14 to 4.19. A serial processing is performed in the case of translations (4.14) and user dialogs (4.16), and in search engines (4.17).

In the case of other functions, a recursive process with (4.7), (4.9), (4.11) will often be necessary beforehand. Recursive loops are performed in advance, particularly in the case of speech recognition (4.15), spell-checking (4.18) or word recognition (4.19). Here, the processes 4.5.1 and 4.5.2 also play a more important role in the interaction with the user than is the case for the other functions.

A very important operational advantage of the invention is that, in the case of interactive operation, it is always clear to the user how good his text is in terms of semantic univocality, and that he can intervene directly. People who write well, in the sense of comprehensibility, grammar and syntax, barely receive any queries from the system.

If the system is used off-line, e.g. when translating large quantities of text, the system can be configured such that all queries can be post-processed in batch mode.

Explanatory Notes to FIG. 6

For the assignment of the claims in section 4, the illustration in FIG. 6 was chosen. In FIG. 6 the recursivity of the processes of steps 4.5 to 4.11 is shown more formally and associated with individual results, in order to be able to formulate the claims more easily. To allow understanding of the processes in the system themselves, simpler explanations for a person skilled in the art are possible with FIG. 4.

Modulator (2) of FIG. 6 represents in practice the multiple passes 4.5 to 4.11 which take place until there are no more words with basic spelling errors. Modulator (3) of FIG. 6 shows the multiple recursive passes which take place until the analysis of the sentence itself in the morphological, syntactic sense, and its univocality measurement, are complete.

In this sense FIG. 4 contains a highly operational representation of the invention to better explain the individual functions. FIG. 6 contains a formally simplified view of the invention to better illustrate different claimed areas of application of the invention. FIGS. 4 and 6 therefore differ only in the degree of abstraction of the representation, but have no functional differences.

3.2 Explanations to FIG. 3.1

The table of FIG. 3.1 is to be regarded, in a figurative sense, as the 2-dimensional schematic diagram of a more than 3-dimensional number space. It explains the structural, configurational and assignment principle of meaning-signals, but is not a visually comprehensible structure itself.

Expressed in highly simplified terms, a meaning-signal is the content of a column in FIG. 3.1, from column “D” onwards.

Meaning-signals constitute a computational tool which enables the software algorithms of the invention—that are controlled automatically by the current text and context—to extract implicit information from texts.

FIG. 3.1 shows an extract of the meaning-signals for 9 words, which is readable in 2 dimensions. (For words see coordinates D1 to M1). FIG. 3.1 is also an aid to make FIG. 3.2 easier to comprehend. The sentence: “Der Stift schreibt nicht” (The pin/pen/institution etc. does not write/author) is analyzed. These words are listed in FIG. 3.1.

The headings in lines C1-M5 contain general remarks on the words. From line 6 invention-specific content is displayed. It should be noted that the information in line 3 represents standard dictionary information that has no invention-specific relevance, because no modulation between homonyms and complementaries can be calculated with them.

Lines 9 to 42 show for each word an extract (approximately 10% of the total content) of its meaning-signal. Columns B and C (meaning-signal category 2 and meaning-signal category 4) represent a verbal assignment—i.e. a feature description—of the respective individual meaning-signal value. They are only shown for explanation purposes. Line 7 contains for each word the number of occupied fields in the meaning-signal and to the right of the slash, the number of constraint references (CR) e.g. for “schreiben 1” (to write) 86\3.

Constraint references are situational attributes, according to which the values of categories in meaning-signals can be automatically switched on or off depending on the context. For example, during its construction, a building (“Stift 4.1” column I, lines 10, 37, 39, 41) is assigned properties (=features+values) with the abbreviation H (for German ‘Herstellung’ (=construction)) which the building no longer has during its subsequent usage, only during its construction period.

The suffix F, e.g. in cell F27 for “Stift 1”, indicates a functional requirement. Homonyms of a word without a regular, fixed surface will modulate with “Stift 1” less well than those which have a fixed, regular surface.

Other attributes are activated, e.g. by the constraint references (CR), when meaning-signals occur in the environment of the word which are assigned to the trigger words in line 6 of the meaning-signal.

It is important to note that, in this manner, a pattern of the constraint references (CR) in the sentence is also produced, which also generates—like the modulation of homonyms with complementaries—non-explicit, contextual information.

For example, the sentence: “Der Stift (3) hört dem Lehrer nicht zu.” (The institution (3) does not listen to the teachers.) contains a (CR) pattern including “School 9 (institution or building)”, which in turn can become a complementary for other homonyms in the context of the sentence as a meaning-signal. The meaning-signals of (CR) patterns are automatically retrieved by SenSzCore during the calculations and combined, automatically saved or continuously updated over several sentences, or to the end of a paragraph of a text.

These effects are the basis for the fact that logical conclusions can also be drawn from the context with meaning-signals using (CR). (CR) are therefore also one of the bases on which SenSzCore in the case of unique sentences, can also automatically “read between the lines”.

Especially in combination with e.g. adverbs of all types, temporal\spatial\justifying\or modal prepositions or logical operators (not, and, or, etc.), in many sentences logical inferences can also be identified and stored in an appropriate manner for further processing. (Embodiments No. 44-47)

Since for (CR) the meaning-signals are known, all synonyms, hypernyms and hyponyms of (CR) can also become active, including all of their inflections, in the same way as the explicitly specified (CR) itself. For example, if “Gebäude” (building) is entered in a word as a (CR), then e.g. “building site”, “high-rise”, “house”, “government building”, etc. and all their declensions and plurals are also activated automatically in the “meaning-checking”, with differences between more general expressions or more concrete ones, such as government building, also being included in the meaning-signal. In “government building”, positions in the meaning-signal which contain social-political components are occupied, which in turn are associated with the constraint reference exercise of profession.

It should be noted that in the operative embodiment, the (CR) marking takes place with non-numeric characters in a different indexing level. Thus, in the arithmetic part, meaning-signals always contain arithmetically processable values. All other components are contained in other index dimensions and can be automatically retrieved or combined.

The features in columns A, B and C of the individual meaning-signal values do not represent partial definitions of the words in themselves, but e.g. associations of the common sense such as would be given if someone were asked to sketch a pictorial story for the word in question. This pictorial story must illustrate which features are associated—even in abstract form. In this sketch must be shown which acting subject types/object types, which triggers, which dimensions have relevant associations when the word is used, etc. For understanding the structure of meaning-signals, in the broadest sense, the basic principles of the design of design catalogs {Konstruieren mit Konstruktionskatalogen ISBN 3-540-67026-2} may be useful.

Because categorizations are always arbitrary and relative, the categorization cannot make any absolute claims for meaning-signals either. The best that can be achieved is to assess the degree of usefulness of each categorization in relation to its intended application. The primary benefit of this form of categorization of the meaning-signals of words is that it is structured in such a way that:

-   1. As few features as necessary must be used. -   2. As many features are included as necessary such that for all     words in a language, sufficiently many relevant associations are     indicated, so that homonyms are only modulated by the correct     complementaries. -   3. Association levels are included which, depending on the     application environment of the word, can affect the meaning-signal     (=constraint references (CR) in line 6). It should be noted that all     trigger words of the (CR) occur in the homonym notation     (=Word+current homonym number in our databases). Each one therefore     has its own fixed basic meaning-signal, regardless of the inflection     in which they occur. -   4. The modulation of homonyms of a sentence by complementaries with     maximum frequency in the sentence/context thus ultimately     corresponds to the way in which a human being with a good knowledge     of the high-level language would assess the sentence for     univocality.

The derivation of the meaning-signal categories themselves is based to a large extent on a tree structure, building on the basic elements of matter, information, energy and time supplemented by emotional, vegetative, trigger, process, and spatial/place features. Category 1 is upstream of Category 2. In this diagram—for reasons of space—Category 3 is included in Category 2. Category 4 represents the comment that the authors of meaning-signals read—when creating the database of the invention—in order to assign a value to the meaning-signal or not. The volume of work involved in creating meaning-signals roughly corresponds to the effort involved in writing a large dictionary, but with a very specific, numeric notation. The assignment of the individual values in the meaning-signal is in the majority of cases fuzzy (closer to yes, closer to no) and in the case of yes, with values that are greater than 1 if “a lot” of the individual association is present. Other assignment forms are used e.g. in the case of material properties, such as density to water (FIG. 3.1 line 17). Here the value 1=lighter, 2=equal, 3=heavier. The same applies to air.

Such values lead to the result that, e.g. in the sentence: “Das Fahrzeug schwebt in der Luft.” (The vehicle floats in the air), the meaning-signal of a Zeppelin with the (CR) “usage” has a higher modulation with “float”, than for example, a “car” or an “aeroplane”. In the case of a car or plane, a compatibility query to a logic inference program can even be initiated.

3.3 Explanations to FIG. 3.2:

Seen here is the extract of the calculations for the sentence: “Der Stift schreibt nicht.” (The pin/pen/institution . . . does not write/does not author.) This sentence does not have a unique meaning.

The verb “schreiben” (to write, etc.) has 4 meanings and “Stift” has 12. Fields 1.1 to 4.20 are irrelevant, because they are symmetrical to the occupied fields, without additional information.

Black, diagonal fields are irrelevant, since they represent comparison of each word with itself.

Fields 1.1 to 4.4 and 6.6 to 20.20 are also irrelevant here, since they only compare meanings of a homonym with each other.

In the matrix 35 cells are marked with “XX”. Other fields contain figures between 30% and 100%.

“XX” means that computational, logical and or morphological/syntactic comparisons between the meaning-signals of the meanings involved have led to the exclusion of the combination.

Percentage values represent the degree of meaning-modulation of the meaning-signals of the words that intersect in that field.

The cells marked with XX in this case refer specifically to the fact that

-   a. in “schreiben 1”, the verb does not allow any motor activity by     the subject of the sentence, if this is an item: in that case only a     function such as “schreiben 3” can be exercised here -   b. “schreiben 3”, i.e. the writing function of a tool/device—cannot     be applied to a living being as the grammatical subject (“Stift”) -   c. in the case of “das Stift” (lines 9, 10, 13, 14, 15, 16) for     example, it is additionally the case that the article (gender) does     not match that of the example sentence. -   d. In line 4 no “XXs” are entered as the variant is entirely absent,     (in the example sentence there is no reflexive usage of ‘schreiben’     (to write))

If we now automatically write a list with the modulation results sorted by descending size, a meaning-signal intersection ranking (SSIR) is obtained.

To see an overview of the remaining possibilities, the ‘autotranslation’ function is used: it shows each one of the alternatives by displaying the relevant words in terms of their most common synonyms (underlined in the examples) of the homonym in context in the input language of the user.

According to the number and the value of the largest values, the following analysis, or autotranslation, is generated automatically from the SSIR. The value of 66% is an empirically determined value that can be specified individually according to the ontology and language and represents a lower, relative relevance limit for meaning-modulation:

-   1. The sentence ‘Der Stift schreibt nicht.’ does not have a unique     meaning and admits [5] possible relevant interpretations >66%:     (underlined words=synonyms for Stift or schreiben)     -   i schreiben 3 (as function), with Stift 1 (pen).         Autotranslation: The pen does not work.     -   ii schreiben 2 (create readable work with text), with Stift 3         (apprentice) or Stift 5 (nipper, brat)         -   Autotranslation: The apprentice does not author.         -   Autotranslation: The nipper does not author.     -   iii schreiben 1 (motor activity), with Stift 3 (apprentice) or         Stift 5 (nipper, brat)         -   Autotranslation: The apprentice is not writing down.         -   Autotranslation: The nipper is not writing down.     -   The remaining combinations result in lower values. For example,         as a machine translation system e.g. in the area of everyday         business usage (technical, commercial, scientific language), the         variants ii and iii would be ruled out as “Stift 3” is defined         within the meaning-signal only for <regional application>,         whereas “Stift 5” is defined as <jocular>. Therefore the only         remaining interpretation is that the pen is not working. -   2. The user is automatically given the choice to accept Option 1 by     SenSzCore and an automatic indication of the remaining possibilities     is given in ii and iii.     -   Important note: the numerical modulation values are based on the         properties of the meaning-signals that the system was previously         manually “taught” and are permanently stored. The values of the         meaning-signal therefore reflect the associations of “one”         person, namely the person who created the relevant         meaning-signals, and not an absolute decision in itself. As a         consequence, the modulation value of 2 meaning-signals is of         course also not an absolute, but a relative statement.     -   Also, in making the decision for i there is no statistical         evaluation used, because it was actually counted—not         extrapolated—and alternatives e.g. below the limit of 66% were         discarded.

Explanatory Notes to Table 5

Table 5 shows the comparison of the best commercially available programs (as of January 2014), on the basis of 5 example sentences:

-   I) Der Stift kauft ein Stift. “The Stift (masc) buys a Stift (neut)” -   II) Der Stift kauft einen Stift. “The Stift (masc) buys a Stift     (masc)” -   III) Das Stift kauft einen Stift. “The Stift (neut) buys a Stift     (masc)” -   IV) Der Stift schreibt nicht. “The Stift (masc) does not author.” -   V) Das Stift wurde in einem Zug geräumt. “The Stift was vacated in     one go.”

The 13 different meanings for ‘Stift’ are listed in FIG. 3.2. Overall, for the 5 example sentences there are 21 possible, relevant meanings. In the prior art only 3 of 189 possibilities are correctly recognized/translated.

The comparison shows clearly that standard commercial programs—whether they are free of charge or not—either cannot calculate several basic facts for meaning detection/do so too seldom, so that in these examples an average hit rate of only 1.5% arises:

For example, programs according to the prior art—in addition to numerous other weaknesses—fail in the following cases:

-   (a) Detection of the gender of nouns, even when an article is     present. -   (b) Differentiation between inanimate object/living     creature/institution. -   (c) Permitted actions of the agent (e.g. things cannot “buy”     anything). -   (d) Detection of the relative proportions of subject and object:     what fits where? For example, “das Stift” (institution) does not fit     into a train (sentence no. V). -   (e) Differentiation of homonyms and their correct translation. -   (f) Warning the user when errors or non-univocality are present in     the text.

Etc., etc.

For other comparative details on the weaknesses of state of the art programs based on examples, see the lower box in Table 5 “linguistic comparison” starting from coordinate C34).

For other typical, process-related errors from the prior art in translation software from the largest companies in the industry, see Table 6.

It is clear that with this prior art (which has been optimized for over 25 years), no serious work is possible.

No matter what the source language and the target language are—e.g. within European languages.

Hereafter, some of the different embodiments of the invention are described in a structured form.

-   1. The starting point is a computer—implemented method of     “meaning-checking”, which automatically converts the semantic     meanings of the words in a natural language sentence which are not     explicitly present into numbers—called meaning-signals—and which     deterministically calculates correct meanings of all the words of     the sentence for the sentence context with the meaning-signals,     characterized in that:     -   it is stored in a non-transitory, machine-readable storage         medium and equipped with instructions executable by a computer,         such that when these are executed by a computer processor,         cause, for a sentence to be analyzed—beginning and ending         according to the applicable rules of the natural language—of a         text of the natural language, all available meaning-signals         according to the invention to be automatically extracted for         each word from the computer-implemented memory (1) and the         arithmetic and logical comparison of the meaning-signals of all         of the words of the sentence with each other—controlled only by         the words themselves and by their specific arrangement in the         analyzed sentence—is carried out in the meaning modulators (2)         and (3) in such a way that each word, using its meaning-signals         calculated as valid for this context, by means of associated,         processing-relevant comparison data relative to other         meaning-signals automatically created in the analysis separately         for each word and assignable to the word, is tagged in a         machine-readable form with other words of the sentence, and         subsequently explicitly with the information, such that it can         be automatically deduced from this tagging whether the word in         the context is spelt correctly and whether the word has only one         or multiple meaning-signals in the context and what these         meaning-signals are. -   2. Method according to No. 1, characterized in that, once the     meaning score has been calculated for all the words in a sentence in     the meaning modulator (2), the following information is available in     machine-readable form:     -   2.1. If the meaning score “SW” for a word of the sentence is         equal to 0 (zero), then the word is spelt incorrectly and the         sentence receives the sentence score “SS”=0.     -   2.2. If the meaning score “SW” for a word of the sentence is         greater than 1, then the analyzed sentence is incorrect, or not         univocally formulated, because words with SW>1 have more than 1         possible meaning in the sentence. The sentence receives the         sentence score “SS”=“SW”. If more than 1 word of the sentence         have meaning scores>1, then the sentence score “SS” is set to         the maximum value “SW” of the meaning scores of the words of the         sentence.     -   2.3. If all the words of the sentence have a meaning score         “SW”=1 then the sentence is univocal and receives the sentence         score “SS”=1     -   2.4. If words have a meaning score “SW”=−2, then they allow both         upper and lower case spelling. The sentence score SS then         receives the value SS=−2, until the correct upper or lower case         spelling of the words with SW=−2, in this sentence, is finally         calculated using further iterative steps. -   3. Method according to No. 1 or 2, characterized in that for     sentences that no longer contain any words with SW=0, it is     calculated in constraint modulator (3) what sentence score “SS” they     have when the constraint references (CR) present in the     meaning-signals are used, and the following resulting information is     available in machine-readable form:     -   3.1. If the meaning score “SW” for a word of the sentence is         greater than 1, then the analyzed sentence is incorrectly or not         univocally formulated, because words with SW>1 have more than 1         possible meaning in the sentence. The sentence receives the         sentence score “SS”=“SW”.         -   If more than 1 word of the sentence have meaning scores>1,             then the sentence score “SS” is set to the maximum value             “SW” of the meaning scores of the words of the sentence.     -   3.2. If all the words of the sentence have a meaning score         “SW”=1 then the sentence is univocal and receives the sentence         score “SS”=1 -   4. Method according to at least one of No. 1 to 3, characterized in     that in words with SW=0, a storable error message is launched, which     in particular indicates spelling errors of all the words of the     sentence, naming the relative word position in the sentence, the     cause of the error and displaying possibilities for eliminating the     error calculated from the memory of the database system (1), and is     stored sequentially in the error-message-storage (4). -   5. Method according to No. 4, characterized in that in words with     SW=−2, a storable error message is launched, which in particular     indicates the presence of case errors in the spelling of all the     words of the sentence, naming the word position in the sentence, the     cause of the error and displaying possibilities for eliminating the     error calculated from the memory of the database system (1), and is     stored sequentially in the error-message-storage (4). -   6. Method according to at least one of No. 1 to 5, characterized in     that together with the current sentence, depending on availability,     up to “n” immediately preceding sentences which have already been     processed according to No. 1 and have sentence score=SS=1, are read     in and the meaning-signals of their words are processed in the     meaning modulator (3). -   7. Method according to at least one of No. 1 to 6, characterized in     that the syntactic sentence components such as are present in the     sentence (main clauses, dependent clauses, inserted dependent     clauses, subjects, predicates, objects, text parts between hyphens,     text parts between two brackets (open/closed), etc.) are determined     and stored in the sentence part memory (6) individually,     sequentially, and retrievably with all the words that form them. -   8. Method according to at least one of No. 1 to 7, characterized in     that in the meaning modulator (3) the main theme of the current 3     sentences, if each of their sentence scores=1—where they exist—are     updated on a rolling basis. -   9. Method according to at least one of No. 1 to 8, characterized in     that in the constraint modulator (3) the main theme—as the most     frequent, valid constraint reference (CR) from (3), for example also     in the form of its meaning-signal—of the current paragraph, in the     form of the meaning-signals of the constraint references, is updated     on a rolling basis and is made hierarchically retrievable. -   10. Method according to at least one of No. 1 to 9, characterized in     that in the case of sentences with SS>1 an autotranslation message     is generated, which lists the still existing #SW meaning     possibilities of each word and in each case retrieves the most     common synonyms of each word from the database system (1) using its     valid meaning-signals and stores them sequentially in the     autotranslation storage (5). -   11. Method according to at least one of No. 1 to 10, characterized     in that, for words in which SW is not equal to 1, formatting     elements are specified in the error-message-storage and the User     Interaction Manager (7), that can be used in text editing programs     to store the status of the word from the autotranslation storage (5)     or the error-message-storage (6) for each affected word, e.g.     visually on the display device of the user and, for example, to     generate “mouse-over” information on the display device of the user. -   12. Method according to at least one of No. 1 to 11, characterized     in that, from interactions of the user in relation to the User     Interaction Manager (7) regarding correction suggestions originating     from the autotranslation storage (5) or the error-message-storage     (4), the text in the sentence is updated and a new calculation run     according to No. 1 is carried out for the sentence, wherein all     entries in the autotranslation storage (5) or the     error-message-storage (4) are adjusted to match the latest     processing state of the sentence. -   13. Method according to at least one of No. 1 to 12, characterized     in that, the current topic structure from modulator (3)—continuously     updated—is displayed to the user via the User Interaction Manager     (7) in a separate window, for example on the display device used. -   14. Method according to at least one of No. 1 to 13, characterized     in that, when the sentence reaches the score SS=1, an     autotranslation is generated which retrieves the by now single     meaning-signal of each word from the database system (1) and in each     case retrieves the most common synonym of each word from the     database system (1) using the valid meaning-signal and tags each     word of the sentence with both information items or with     corresponding, machine-readable alternative labels (8). -   15. Method according to at least one of No. 1 to 14, characterized     in that, when enabling the autotranslation, the user can also     retrieve more than the most common of the synonyms of the tagged     word with SW=1 from the database system (1), in order then to     replace the original word of the sentence with that selected from     these other synonyms. -   16. Method according to No. 15—named “autotranslation”—characterized     in that, if the user marks a sentence with score 1—e.g. with the     mouse via his display device—a grammatically correct sentence is     automatically formulated from the tagged information of the     sentence, in which e.g. the inflectable homonyms of the sentence are     replaced by their most common synonyms. -   17. Method according to at least one of No. 1 to 16, characterized     in that, if the user actively selects a word with SW=1 in a sentence     with sentence score SS=1—e.g. by double-clicking with the mouse via     his display device—from the tagged information of the sentence the     most common synonym of the selected word—in the present context—is     automatically displayed. -   18. Method according to at least one of the previous No. 1 to 17,     characterized in that, for words of the text in sentences whose     score SW is not equal to 1, they are re-tagged with the existing     information for the respective word from autotranslation storage (5)     or the error-message-storage (4) via the User Interaction Manager     (7), whenever the information for the respective word is changed in     both these memories. -   19. Method according to at least one of No. 1 to 18, characterized     in that, all information from preceding sentences which is necessary     for the analyzed sentence to obtain a score SS=1 for the sentence,     are tagged for subsequent further processing. -   20. Method according to No 19, characterized in that all corrections     of the sentence for words with SW not equal to 1 are carried out     automatically, provided the correction of the word has only 1 valid     possibility in the modulator 1 or error memory (4). -   21. Method according to at least No. 19 or 20, characterized in that     all messages generated during the processing of the sentence and not     according to No. 20 can be deleted automatically, are tagged on the     sentence in off-line mode and the method continues with the next     sentence with status sentence score SS=“unknown”. -   22. Computer-implemented machine translation system for translating     sentences of one natural language into another, by using     “meaning-checking” according to at least No. 1 to No. 21. -   23. Method according to No. 22, characterized in that, a sentence     with score SS=1 is automatically acquired, or the text is processed     according to No. 1 until at least 1 sentence with sentence score=1     exists, or there are no unprocessed sentences left. -   24. Method according to at least No. 22 or 23, characterized in     that, the text is translated into the selected target language of     the user, taking into account the pre-designed, univocal     meaning-signals of all words and all additional information with     which they are each tagged.     -   Use for this purpose of the database of the database system (1)         which contains all meaning-signals, and associated therewith,         the correct translations of all words in the source and target         language in conjunction with their valid meaning-signals in all         inflections in the source and target language. -   25. Method according to at least one of No. 1 to 24, characterized     in that, language-pair-specific rules of the database system (1) are     applied, which by adjustment of the order of the words in relation     to their morphology and inflection, and of the order of the sentence     constituents from No. 7 in memory (6), places the sentence in the     target language in an order that is semantically, morphologically,     grammatically and syntactically correct in the target language. In     doing so, particular account is taken of e.g. the tagged sentence     structure of the source language from No. 7, which in a     language-pair-specific manner also specifies the correct, new order     of the sentence parts in the target language. -   26. Computer-implemented processing of texts originating from     automatic speech recognition of a natural language, according to the     prior art, using “meaning-checking” according to at least one of No.     1 to 21, characterized by: -   27. Method according to No. 24, characterized in that, text with     sentences from a speech recognition system according to the prior     art is acquired automatically. -   28. Method according to No. 26 or 27, characterized in that, a     calculation is performed of the existence of homophones in a     sentence by comparison of the words of the sentence against the     known homophone groups in the natural language of the user from the     database of the database system (1). -   29. Method according to at least one of No. 24 to 28, characterized     in that, all possible sentence variants are generated by sequential,     reciprocal replacement/substitution of the relevant homophone     variants in the sentence. -   30. Method according to No. 29, characterized in that, each sentence     is evaluated according to at least one of the methods according to     No. 1 to 22 and is tagged in off-line mode with messages from the     autotranslation storage (5) or the error-message-storage (4). -   31. Method according to No. 30, characterized in that, the sentence     scores of all generated sentences are evaluated and, if only one     single sentence of all of them has the score SS=1, this sentence is     utilized as a result and tagged in accordance with No. 14. -   32. Method according to No. 31, characterized in that, the sentence     scores of all generated sentences are evaluated, and if more than 1     sentence has a score=1, the one with the highest arithmetic match of     all homophones is taken. -   33. Method according to at least one of No. 1 to 32, characterized     in that, if no unique decision is possible because none of the     sentences has a score SS=1, the input sentence is tagged with the     information on the analyzed homophones, the messages from the     autotranslation storage (5) or the error-message-storage (6).     -   The advantage of this variant with respect to the state of the         art is:     -   speech recognition according to the prior art cannot recognize         homophones, or upper/lower case spelling. By the procedure shown         in No. 26, in all known homophones of a natural language that         are recorded in the database of the database system (1) (e.g.         approx. 1,000 in German and in some cases very frequent ones,         such as er/eher, ist/isst, jäh/je, sie/sieh, Feld/fällt, etc. In         other languages 10,000—English, up to 25,000—Japanese), the         correct spellings in the sentence context are identified via         their meaning-signals. This reduces training costs for operating         the software and increases the quality of the recognized text         considerably. -   34. Computer-implemented processing/reconstruction of garbled texts,     e.g. from automatic speech recognition of a natural language in the     presence of background noise, according to the prior art, with     spelling errors but no completely missing words using     “meaning-checking” as claimed in at least one of claims 1 to 21. -   35. Method according to No. 34, characterized in that, in an     automatically acquired text the possibilities of rewording the     sentence are determined systematically by the correct spelling of     incorrect words. This can be effected, for example, by “sounds-like”     methods or similar search algorithms on the basis of data from the     database system (1). Firstly with the priority on words that are     similar to homophone groups, or that correspond to omissions of     letters or typical typing errors when operating a keyboard,     including upper/lower case, accenting, etc. -   36. Method according to No. 34, characterized in that, with the     facilities provided in No. 35 it is investigated whether sentences     with a sentence score SS=1 are produced. -   37. Method according to at least one of No. 34 to 36, characterized     in that, the procedure is terminated if no usable hits can be     identified after a user-specified time—e.g. 5 seconds−(scale=approx.     500 . . . 1000 attempts per second). -   38. Method according to at least one of No. 34 to 37, characterized     in that, the input sentence is tagged with the information of the     analyzed homophones, the messages from the autotranslation storage     (5) or the error-message-storage (6). If only sentences with a score     unequal to 1 exist, those having the fewest words with SW=0 are     prioritized for the tagging. -   39. Computer-implemented operation of search engines that search in     databases, the natural language texts of which are tagged by     “meaning-checking” according to at least one of No. 1 to 21 and are     indexed based on the tagging. -   40. Method according to No. 39, characterized in that an automatic     database indexing is carried out based on the meaning-signals of all     of its words according to No. 1, before the search process and of     all sentences which have a sentence score SS=1 according to at least     one No. 1 to 21 and have been tagged accordingly. -   41. Method according to at least one of No. 39 or 40, characterized     in that, an automatic inclusion of all same-language synonyms in all     their valid inflections is included in the search (same     meaning-signal as the search word). -   42. Method according to at least one of No. 39 to 41, characterized     in that, an automatic inclusion of foreign-language synonyms in all     their valid inflections is included in the search (same     meaning-signal as the search word). -   43. Method according to at least one of No. 39 to 42, characterized     in that, when using multiple search words, a combination of the     meaning-signal hits according to the association logic of the search     words is carried out.     -   The operation of search engines according to the procedure shown         in No. 39 to 43, has the enormous advantage that the search only         produces hits that correspond to the meaning-signal of the         search word. This reduces the number of hits in search engines         by more than 99% if the search word is a homonym. In addition,         the valid inflections of the search word and all those of its         synonyms are also automatically searched for, if required in         foreign languages as well. This increases the quality of the         search result significantly, especially for business         intelligence applications and reduces the reading effort         required for the user to select the final hits, in inverse         proportion to the quality gain. -   44. Computer-implemented evaluation of the relevance of statements     in the form of text in natural language to a pre-defined topic     according to at least one of No. 1 to 21. -   45. Method according to No. 44, characterized in that, in the case     of an automatically acquired sentence with sentence score SS=1, the     meaning-signals of the words of the sentence with pre-defined     combinations or patterns of meaning-signals are automatically     composed with words of the comparison topic tagged according to No.     1. -   46. Method according to No. 44 or 45, characterized in that, the     overlap of the meaning-signals of the topic specification and the     input sentence with pre-defined overlap patterns is ranked, taking     into account the existence of meaning-signals of logical operators     (e.g. “not”, “and”, “or”, etc.) within the sentence structure of the     input sentence according to any one of No. 1 to 22. -   47. Computer-implemented conduct of automatic dialogs by     computers/or “responding computers” with human users, by combining     the claims of “meaning-checking” according to No. 26, 34, 39, 04. -   48. Method according to No. 47, characterized in that, the spoken     input of a user is acquired as text by the responding computer by     using No. 26, 34, 39, 04. -   49. Method according to No. 47 or 48, characterized in that a     breakdown of the input text into individual sentences is carried out     by the responding computer, and an automatic evaluation is made as     to which of these sentences are statement sentences and which are     question sentences, for example by the presence of question marks at     the end of the sentence or not, or their typical sentence structure. -   50. Method according to at least one of the previous Nos.,     characterized in that, the meaning-signals of the statement and     question sentences of the user are compared according to No. 1,     based on their matching/correspondence with a database tagged     according to No. 47 of the statement sentences, response sentences     and standard question sentences of a machine-readable text ontology     of the responding/dialog-participating computer, which exists in the     same natural language as the natural language in which the user     interacts.     -   (The scale for the ontology of the responding computer=e.g. 500         accurate sentences of an FAQ-database of a supplied service,         e.g. each with sentence score SS=1). -   51. Method according to at least one of the previous Nos.,     characterized in that in the case of matching values of the     meaning-signals of the sentences of the user above a certain level,     with the computer ontology of the responding computer, the response     and statement sentences rated the highest in the     matching/correspondence value are identified from the computer     ontology. -   52. Method according to at least one of the previous Nos.,     characterized in that, the responding computer generates a     structured, automatic response for the user, e.g. according to the     pattern:     -   (a) confirmation of a maximum of the e.g. 2 highest ranking         sentences A and B of No. 50 of the user in relation to the         computer ontology in spoken form, by the responding computer via         a speech output system in accordance with the prior art. (e.g.,         “If I have understood you correctly, you said the . . . “wording         of sentence A” . . . and also the “wording of sentence B”     -   (b) offering the highest ranking response sentence of the         computer ontology according to No. 50 and concluding with the         highest ranked response sentence from No. 50 of the responding         computer via a speech output system in accordance with the prior         art, which only allows the user to make controlled answers on         request, e.g. “Yes” or “No”.     -   (c) Alternatively answers with the sending of a link by the         responding computer—according to certain rules—which the user         receives, in order to read more detailed information on his         questions and to be able to put more targeted questions to the         responding computer that the user himself might only have found         in the computer ontology e.g. after some search effort of his         own. -   53. Method according to at least one of the previous Nos.,     characterized in that, in the case of matching values below a     certain level, e.g. a standard dialog is called up in the responding     computer, to which the user can only answer Yes or No, or by     uttering controlled pre-defined, spoken, alphanumeric options. -   54. Method according to at least one of the previous Nos.,     characterized in that, an automatic detection is carried out in the     responding computer of the moment from which the intervention of a     human being is needed, e.g. by automatic evaluation of the     redundancy of the dialog or content-based patterns of     meaning-signals in the responses of the user.     -   It should be noted that the enormous flexibility of No. 47 in         comparison to the prior art, which it obtains due to the fact         that meaning-signals according to at least one of No. 1 to 21         are used:         -   The user can speak relatively freely (restrictions are only             the number of different meaning-signals and their             sentence-wise combinations that are included in the computer             ontology).         -   The recognition rate in the computer ontology due to working             with meaning-signals is high and accurate, without the large             amount of programming overhead which is tedious, being             nowadays restricted to specifying particular single words,             or is subject to limitations in the permissible types of             inflection of the recognized words. -   55. Computer-implemented, enhanced spell-checking, by using     “meaning-checking” according to at least one of No. 1 to 22. -   56. Method according to No. 55, characterized in that, the automatic     execution of at least one of No. 1 to 22 is carried out but without     the sentence itself being tagged with the meaning-signals, after     having reached a sentence score>0. The text is therefore only     checked for spelling errors and corrected interactively by the user,     but without necessarily any tagging of the sentence with additional     information taking place. -   57. Computer-implemented word recognition during typing of words on     keyboards which may contain multiply assigned keys, by using     “meaning-checking” according to at least one of No. 1 to 21. -   58. Method according to No. 57, characterized in that the text is     automatically acquired from a subordinate system, such as a user's     smart phone, with word recognition according to the prior art,     tagged with the log file of each of the activated e.g. key sequences     that were used to enter each word in the sentence. -   59. Method according to No. 57 or 58, characterized in that the e.g.     key signals are acquired directly without a selection of words     taking place in advance using another system. -   60. Method according to at least one of No. 57 to 59, characterized     in that, a check of the existing input is carried out according to     at least one of No. 1 to 22, and with the aid of the key sequence     from the log file of the combinations of keys pressed and key     assignments, it is calculated whether other hits of words are     present in the database of the database system (1) for the key     combination of the word whose meaning score in relation to the     existing words of the sentence have a better rating than the     existing ones in terms of spelling, syntax and meaning-signal     matching. -   61. Method according to at least one of No. 57 to 60, characterized     in that, suggestions for improvement of his existing text in terms     of spelling, inflection and syntax of the already existing text are     offered to the user for acceptance. -   62. Method according to at least one of No. 57 to 61, characterized     in that, an automatic correction of typing errors is carried out     during the text input, identifiable as letter sequences which are     not included as word beginning in the database of the database     system (1), but which become so following a change in the letter     order upper/lower case, e.g. according to typical typing error     patterns, while simultaneously taking into account the     meaning-signal matching and the syntax relative to already existing     words of the sentence. -   63. Method according to at least one of No. 57 to 62, characterized     in that, matching words are suggested, e.g. during the input of the     text, as soon as only one single, or less than “n” possibilities     exist for the word which are no more than “m” % longer than the     current word, where “n”>=1; “m”<75%, and which e.g. also have a high     matching value to other already existing words of the sentence in     terms of their meaning-signals. -   64. Method according to at least one of No. 57 to 63, characterized     in that, suggestions or options for the word currently being written     are displayed visually on the user's display device, e.g. above the     word currently being written, in semi-transparent mode. -   65. Method according to at least one of No. 57 to 64, characterized     in that, the text is produced via a speech recognition system     according to No. 26 or No. 34. -   66. Computer-implemented system for the semantic encryption of     sentences of a natural language, using “meaning-checking” according     to at least one of No. 1 to 21. This is claimed in claim 35 -   67. Method according to No. 66, characterized in that, text is read     in, the sentences of which do not necessarily have a sentence score     of 1, but each of which contains at least 3 words with status SW>0. -   68. Method according to No. 66 or 67, characterized in that, “m”     words in each sentence are replaced in a grammatically well-formed     manner, or “n” words are added in a grammatically well-formed     manner, which have suitable meaning-signals compared to their     immediate environment, which indicate that, e.g. by insertion,     negation, relativization or omission or by use of antonyms thereof     from the database of the database system (1), the sentence meaning     can be changed significantly but without the sentence score being     changed. “m”>=1 or “n”>=0. -   69. Method according to at least one of No. 66 to 68, characterized     in that, all alphanumeric chains are proper names and/or dates     and/or pure numbers which have their own meaning-signals, or single     words marked in advance particularly by the user are replaced by     coded number combinations, each of which is not repeated in its     entirety throughout the entire text. -   70. Method according to at least one of No. 67 to 69, characterized     in that the user's starting sentences are stored on the user's     system taking account of the original order, and a log file is     stored of all changes that were created as variants, including for     each change at least a specification of the content of the change     and position in the respective sentence. -   71. Method according to at least one of No. 67 to 70, which assists     the user to identify sentences from other text databases in his     possession than the current text itself, which are similar to the     sentences in the input text to be encrypted, for example, by the     application of No. 44, and that have a sentence score SS=1. -   72. Method according to at least one of No. 67 to 71, characterized     in that, the number of sentences of the text is increased to at     least 7 if over the input text plus variants according to No. 68,     there are less than 7 sentences to be encrypted. This can occur     advantageously, e.g. due to sentences which are determined using No.     71. -   73. Method according to at least one of No. 67 to 72, characterized     in that, a text is created which contains the user's starting     sentences, plus “m” appended sentences which are variants of his     created according to No. 68, that is anonymized according to No. 69. -   74. Method according to at least one of No. 67 to 73, characterized     in that a stochastic scrambling of the sequence of the existing     sentences is carried out and the addition of the explicit     modification of sequence before and after the scrambling to the log     file of No 70. -   75. Method according to at least one of No. 67 to 74, characterized     in that if the unchanged, but scrambled text from No. 73 and the log     file from No. 70 are present, the original text is reconstructed     flawlessly.

In the semantically encrypted text—which does not also contain a single, formally more meaningless sentence, in comparison to those which the user has written himself—the original starting sequence of the sentences of the user is now identifiable only with enormous effort by manual reading. E.g. for 10 starting sentences and 10 additional sentence variants, the original sequence is only 1 possibility among the permutations of 20, i.e. 20!=2.4329*10¹⁸, i.e. approximately 1:2.5 trillion possibilities.

However, each recipient of the text can only restore the starting sentences easily with the information from the log file of the author of the text.

No. 65 can also be used particularly advantageously as an enhancement to standard commercial encryption systems.

If the code of the commercial encryption is cracked, whoever did it would face a practically insoluble time problem due to the amount of sentences to be manually analyzed, in order to determine the true meaning of the whole text, from which moreover all information referring to people, dates and numbers is missing, information which also includes modified quantifiers and logical operators as compared to the original text.

Here the only remaining risk is the secure transmission of the code for the starting sequence according to at least one of the previous claims, in addition to the secure transmission of the standard commercial encryption code.

Even with the application of our own method according to No. 1 no decryption would be possible, since only sentences with a univocality level similar to the univocality level of the original text are present in the scrambled text.

TABLE 1 Extract of the homonyms and translations from the dataset (1) of FIG. 6 2|Meaning signal raw components 3|verbal meaning 1|Word (highly simplified) indication 4|Spanish 5|English Drehung 1 <1dr><2de> . . . [Kreisbewegung] rotation, . . . rotation, . . . Drehung 2 <2de><3d><teil> . . . [Schwenkung] pivotacion, . . . swing, . . . Drehung 3 <Naut><2de> . . . [Haise, Wande, virada, . . . racking, . . . Kurswechsel] Drehung 4 <math> . . . [Transformation] giro, . . . rotation, . . . Drehung 5 <foto, film> [Kameraschwank] giro, . . . panning, . . . Drehung 6 <abl><akt> [daa Sichdrehen] el girer, . . . gyration, . . . Lauf 1 <match>.. [Gang] funcionamiento, . . . operation, . . . Lauf 2 <Sport> . . . [Rennen] carrera, . . . run, . . . Lauf 3 <fig.de> . . . [Veriauf der Dinge] transcurso, . . . course, . . . Lauf 4 <masch> . . . [Betrieb] marcha, . . . running, . . . Lauf 5 <Mus> . . . [Tonfolge] frase, . . . riff, . . . Lauf 6 <2ool><Hunt> . . . [Bein] pata, . . . leg, . . . Lauf 7 <waff><1dr><hohl> . . . [Gewehrlauf] cana, . . . barrel, . . . Lauf 8 <Sport> . . . [Durchgang] prueba, . . . beat, . . . Lauf 9 <edv> . . . [Programmlauf] ejecucion, . . . run, . . . Lauf 10 <geog.hydr> . . . [Plusslauf] curso, . . . course, . . . Lauf 11 <bew><Mot><ugi.getr> . . . [Hub] carrera, . . . stroke, . . . Lauf 12 <strad> . . . [Strabenverlauf] transcurso, . . . run, . . . Lauf 13 <auch Atom, [auf bestimmter Bahn] recorrido, . . . run, . . . Raumf><Astr><2de> <3d> . . . Lauf 14 <gieB> . . . [Kanal] canal de launder, . . . colada, . . . Lauf 15 <bau> . . . [Treppa] volada, . . . flight, . . . Geschoss 1 <waff><1dr.tim4> . . . [Projektil, Kugel] proyectil, . . . projectile, . . . Geschoss 2 <Bau> . . . [Etage] piso, . . . floor, . . . Geschoss 3 <sport><co1log> . . . [scharf geachossener canonazo, . . . shot, . . . Ball] Note: The meaning signals are multi-dimensional number fields whose first 2 . . . 3 raw components (of approx. 512) are each listed in column 2. (Nomenclature itself - here - is not relevant to the invention. For invention-relevant embodiment, see FIG. 3.1)

TABLE 2 Examples of typical meaning assignment errors made by programs from the prior art English (with machine translation system according to the prior Example art of a well-known No. German search engine provider) B1 Im Zug vom Lauf bekommt das On the train from Geschoss einen Drall um seine running the floor gets a Längsachse. twist about its longitudinal axis. B2 Im Lauf der letzten Minute During the last minute, nahm ich nur einen tiefen Zug I just took a deep train aus der Zigarette. of the cigarette. B3 Das Geschoss muss einen The bullet must have a Gefahrenausgang auf die risk starting on the Rückseite des Gebäudes back of the building. besitzen. B4 Das Geschoss wurde für The bullet was blocked Personen gesperrt, weil ein for people because a Sturm im Anzug war. storm in a suit was.

TABLE 3 Once again, the examples of the difficulty of assigning the correct meaning in ESP in the case of machine translation systems according to the prior art from Table 2, in comparison to the correct translation results obtained by meaning-checking and the application of claim 10 (SenSzCore Translator) in summary form: Incorrect English: German + machine translation system Example correct English: of a well-known search No. SenSzCore Translator engine provider B1 Im Zug vom Lauf On the train from running bekommt das Geschoss the floor gets a twist einen Drall um seine about its longitudinal Langsachse. axis. + In the groove of the barrel the projectile gets a spin around his longitudinal axis. B2 Im Lauf der letzten During the last minute, I Minute nahm ich nur just took a deep train of einen tiefen Zug aus the cigarette. der Zigarette. + In the course of the last minute I just took one deep puff from the cigarette. B3 Das Geschoss muss einen The bullet must have a Gefahrenausgang auf die risk starting on the back Ruckseite des Gebaudes of the building. besitzen. + The floor must have an emergency exit on the rear of the building. B4 Das Geschoss wurde fur The bullet was blocked for Personen gesperrt, people because a storm in weil ein Sturm im a suit was. Anzug war. + The floor was barred for persons because a storm was approaching.

TABLE 4 New terms and names used to explain the invention Word Brief definition Pages Autotranslation Reworded version of the 28, current input sentence in the 35, 36 input language, in which relevant words are replaced by their synonyms, so that the user can determine whether the meaning of the sentence has been correctly detected. User Program module for online 27, interaction operation of the invention, 41, 58 manager which compiles error messages and program information for the user and formats them. Constraint Additional information on 19, 31, reference words, which contains special 32, contextual circumstances relating to boundary conditions of the meaning of the word and is mostly situation- or time-bound. Constraint Program module which 39, 41, modulator calculates inter alia the 60 ranking order of the constraint references for a section of text, based on the frequency of the constraint references of words and their modulation with homonyms and their complementaries. ESP, Electronic Processing of data 11, 15, Sense existing in the form of 23 Processing text, by calculating its meaning in the context and representing it in a computationally processable form. Complementary Word which unequivocally 8, 10, validates the meaning of a 16 homonym or homophone in the context. Degree of Order of magnitude in % 35 meaning by which meaning-signals modulation of words of a sentence overlap Meaning- Procedure for calculating the 1, 3, checking, meaning of words in the FIG. 1 context. Basis for ESP. Sentence Score, The rational number assigned 39, 59 SS, to a sentence of text by meaning-checking, which represents the measurement of its univocality. Semantic Encrypted form in which the 53, 68 encryption original text is semantically modified so that it no longer makes sense overall, but contains no sentences with a lower univocality level than the original. Characterized in that only the author alone can restore the meaning. The encryption code is empirically, e.g. on the basis of the encrypted text itself, non-reconstructable, but only by using the key that is unique for each text. Texts encrypted according to this method are nevertheless e.g. translatable, without the key being known. SenSzCore Name, English abbreviation 10, 11, for meaning-checking = 17 Sentence sense determination by computing of complementary, associative, semantical relationships. Signal List of the remaining possible 35 intersection meanings of homonyms of a ranking sentence in context, sorted in descending order of sentence score. Basis for the autotranslation. Individual See meaning category 17, 19 meaning category Meaning Matrix in which the degree of 3, 5B, Intersection modulation of the meaning- FIG. Matrix signals of individual words 3.2 of a sentence is stored. Meaning Individual component of 2, 57 Category a meaning-signal. Together with an assessment of its presence in a given word, represents a property which can be described with the word - or equivalently with its meaning-signal. Meaning See Complement 16, 25 complement Meaning The fact that meaning-signals 3, 57 modulation can mutually modulate one another in meaning categories in which both meaning-signals are not equal to zero. Meaning-pattern Patterns of values which 3, 58 generate the occupied fields of the Meaning Intersection Matrix. Meaning-pattern See SenSzCore 2, 57 recognition Meaning-signal Numerical representation, as 1, 2, a computational substitute 3, 5, for the meaning of a word; 6, 8, in the case of homonyms for each of its relevant, different meanings. Meaning Score, Rational number, 26, 38, SW representing the number of 39, 57, meanings a word has in its 58 local context Meaning-signal See meaning modulation 3, 62 matching level Trigger word Word which specifies specific, 31, 55 measurable facts for SenSzCore in the captured context Word ligature Fusion of words when 3, 4 speaking, due to the fact that no perceptible pause is heard between the spoken words. [A-prosody, after G. Tillmann] Word score See meaning score

TABLE 5 Comparison of the performance of translation programs A B C D E F G H I J 1 Performance of translationsz compared to other c ross translation error: not so bad 2 translation programs: legend: CORRECT OK, but alternative senses, 3 not detected meanings: der Stifts 7 (therefrom 2 colloquial)\\das Stifts: 3\\schrelben: 4\\kaufen:2(therefrom 1 colloquial)\\Zug: 43\\raumens 12 -> theoretical amount of meanings e.g. of example V = 3 × 43 × 12 = 1548 5 example I II III IV V number 6 computed, 6 4 3 5 3 possi-ble senses 7 German Der Stift kauft Der Stift kauft Das Stift kauft Der Stift schribt nicht. Das Stift wurde in OK not example ein Stift. einen Stift. einen Stift. einen Zug ger{hacek over (a)}umt 8 top 9 1 Suchm The pen buy a pen. The pin buy a pen. The pin buy a pen. The pen does not write. The pin was not cleared 0.2 4 . Anbieter 1 in a train. 9 programs of 2 Suchm. The PIN buys a pen. The PIN buy a pen. The pen to buy a pen. The pen does not write. The monastery was 0.2 4 Anbieter 2 granted in a train. 10 the machine 3 Bezani-SW1 The pin buys a pin. The pin buys a pin. The pin buys a pin. The pin does not write. The pin was in . 0 5 (5) one go vacated 11 translation 4 Bezani-SW2 The pin buys a pin. The pin buys a pin. The pin buys a pin. The pin does not write. The pin was in 0 5 (5) one go vacated. 12 market 5 Gratis-SW1 A pin buys a pin. The pen buys a pen. The pen buys a pen. The pen does not write. The foundation was 0.2 4 vacated in a train. 13 6 Gratis-SW2 The pin will buy a pin. The pin buys a pin. The PIN buys a pin. The PIN does not write. The pin has been 0 5 cleared in a train. 14 7 BezenISW3 A pin buys the pin. The pin buys the pin. The pin buys the pin. The pin doesn't write. The pin was vacated 0 3 (5) in a train. 15 8 Gratis-SW3 Post buys a monastery. Post buys a post Monastery buys a post Post does not write Monastery by one 0.3 4 motion cleared up. 16 9 Gratis-SW4 A pin buys a pen. The pin buys a pin. The pin buys a pin. The pin doesn't write The pin was vacated 0 3 in a train. 18 10 SenSzCore SenSzCore-queries in SenSzCore-queries in SenSzCore-queries in SenSzCore-queries in SenSzCore-queries in German. German. German. German. German. 19 Remarks translation a) monastery? A.1) apprentice? a) monastery? A.1) pencil? a) monastery? 20 1. (partially b) reformatory? A.2) little nipper? b) reformatory? A.2) apprentice? b) reformatory? 21 univocal multiple c) old peoples home? B.1) pencil? c) old peoples home? A.3) little nipper? c) old peoples home? 22 sentences possibilities SenSzCore translation B.2) pin? SenSzCore translation B.1) to author? SenSzCore translation don't for depending SenSzCore depending depending translations on photos translation on B.2) write (motorial action on choice above per sentence) above depending choice above with a pen) a) The monastery n 23 generate a) The apprentice on a) The monastery B.3) write (device function) was vacated i queries from buys a monastery. choice above buys a pencil. translation depending on one move. 24 the system a) The apprentice choice above 2. buys a . a) The pencil does pencil not write. 25 colloquins b) The apprentice b) The apprentice does not b) The reformatory was (Lehring/ buys a pin. c) The little nipper does not vacated in one move. 26 Gbre) or b) The apprentice c) The little nipper b) The reformatory d) The apprentice does not c) The old peoples figurative buys a buys a buys a pencil. home was reformatory. pencil. e) The little nipper does not vacated in one move. 27 entries can d) The little nipper be de- buys a pin. 28 activated c) The apprentice buys c) The old peoples 29 an old peoples home. home buys a pencil. 30 d), e), f) with little nipper 31 Codell An object can't buy You can't buy an You can't buy an a human can't be used as a Monastery [building] does exclusion anything apprentice apprentice device function not fit on a train. 32 criteria buy=<econ> Instruction: depending to vacate: 7 0 information translation depending on choice: siuation of between apprentice = not rich on choice: apprentice: young, learn, danger? (fire, the lines: monastery (building church/ shop floor collapse . . .) (orthogonal institute) = [value]> boarding school, brat child, retreat/millitary/police? codeo-levels) 100kEUA →Question education? cheeky, cute where did he get the social care, pen: paper, Notrt, text, money from? old people/ . . . office . . . 34 Surchen Surchen Bczohi- Bczohi- Bezahl Anbieter Anbieter SW2 SW2 Gratis- Gratis- SW3 Gratis- Gratis- SenSzCore 35 linguistic comparison 1 2 (S) (S) SW1 SW2 (S) SW3 SW4 translation 36 grammatical gender detection 0 33% 0 0 33% 0 0 100% 0 100% 37 gross translation errors (_(•)) (4) + 3 (3) + 5 (5) + 2 (5) + 2 (4) + 4 (5) + 4 (5) + 4 (4) + 4 (5) + 4 0 39 correct syntax in translated sentence 5 5 4 4 5 4 5 0 5 5 40 rating OK outof 5 (mean value 4% 4% 0% 0% 4% 0% 0% 10% 0% 100% state of the art = 2%) 41 sense relevant considerations (extract) 42 43 Differentiation objects/living 0 0 0 0 0 0 0 0 0 100% being/institution 44 (e.g. objects can't buy anything) 45 detection of the relative proportion 0 0 0 0 0 0 0 0 0 100% (what fits into what?) 46 differentiation of homonyms and 0 0 0 0 0 0 0 0 0 100% their correct translation 47 Warning when mistakes or 48 ambiguity is detected 0 0 0 0 0 0 0 0 21 out of 21

TABLE 6 Typical error rates and errors according to the prior art for free translation programs from 2 software/search engine giants on the market. A B C D J K L M N 1 1 English (search engine provider, software provider) Incorrectly Correct Grammar Translation German recognized translation 2 Open machines such as propellers, windmills, and unshrouded unshrouded Fans/ nicht ummantelze ok INCORRECT Offene Maschinen wie Propeller, Windmühlen fans act on an infinite extent of fluid. handein Gebläse/wirken und unshrouded Fans auf einem unendichen AusmaB Flüssigkeit handein. 3 Closed machines operate on an finite quantity of fluid as bedienen/Gehäuse. wirken/Ummantelung ok INCORRECT Geschlossene Maschinen bedienen auf einer it passes through a housing or casing. endichen Menge von Flüssigkeit, wie es durch ein Gehäuse oder Gehäuse. 4 With gentle puffs you can unclog your pipe, but you risk Rohr/Sprünge Pfeife/entstopfen FALSCH INCORRECT Mit sanften Zügen können Sie ihr Rohr to swallow the ash. Sprünge helfen, aber Sie riskieren, um die Asche schlucken. 5 The flat hurt me on my feet. Wohungen Schlappen FALSCH INCORRECT Die Wohnungen auf meine FūBe tun weh. 6 If you see a flat you have to lower the tone. Wohnung Erniedrigungszeichen FALSCH INCORRECT Wenn Sie eine Wohnung, die Sie haben sehen, um den Ton zu senken. 7 He drove his flat to the parking. Wohnung Pritscherwagen ok INCORRECT Er fuhr seine Wohnung, bis zum Parkplatz. 8 I had a long puff from the pipe. Rohr Pfeife ok INCORRECT Ich hatte einen langen Zug aus dem Rohr. 10 2 English (search engine provider) German 11 Open machines such as propellers, windmills, and unshrouded Fans, Ausdehnung Gebläse/AusmaB FALSCH INCORRECT Offene Maschinen wie Propeller, Windmühlen, fans act on an infinite extent of fluid. und halboffenen Fans wirken auf einer unendichen Ausdehnung der Flüssigkeit. 12 Closed machines operate on an finite quantity of fluid as it Gehäuse Ummantelung FALSCH INCORRECT Geschlossen Maschinen arbieten auf einer passes through a housing or casing. endichen Menge von Flüssigkeit, wenn es durch ein Gehäuse oder Gehäuse gelangt. 13 With gentle puffs you can unclog your pipe, but you risk to Rohr/Sprünge Pfeife/entstopfen FALSCH INCORRECT Mit sanften Zügen können Sie ihre Rohr swallow the ash. Sprünge zu helfen, aber Sie riskieren, um die Asche schlucken. 14 The flat hurt me on my feet. Wohungen Schlappen FALSCH INCORRECT Die Wohnung verletzt mich auf meine FūBe 15 If you see a flat you have to lower the tone. Wohnung Erniedrigungszeichen FALSCH INCORRECT Wenn Sie einen Flach sehen, müssen Sie, um den Ton zu senken. 16 He drove his flat to the parking. Wohnung Pritscherwagen FALSCH INCORRECT Er fuhr mit seinem flach auf den Parkplatz. 17 I had a long puff from the pipe. Biattertelg/Rohr Zug/Pfeife FALSCH INCORRECT Ich hatte eine lange Blatterteig aus dem Rohr. 19 3 German (search engine provider, software provider) Incorrectly Correct Grammar Trans- English recognized translation 20 Wir werden die Preise anziehen. attract rise ok INCORRECT We will attract the prices. 21 Boris Becker machte seinen wichtigsten Punkte beim Aufschlag. upon impact at the serve ok INCORRECT Boris Becker made his most important points upon impact. 22 Nach diesern Fehlschlag musste er mit einer Anzeige rechnen. reckon/display count/ ok INCORRECT After this failure he had to denunciation reckon with a display. 23 Der Läufer ist ein Teppich dessen Länge viel gröBer lst, als die rotor rug — INCORRECT The rotor is a carpet of whose Breite. length much is greater than the width. 24 Im Zug der Feuerwehr waren mehrere Belcannte. train/fire procession/ FALSCH INCORRECT In the train of fire were fire brigade several acquaintances. 25 Der letzte Zug des Schachspielers war ein Fehler. train move ok INCORRECT The last train of the chess player was a mistake. 26 Vor dern Zug marschierte ein Fahnenträger. train march ok INCORRECT A flag bearer marched before the train. 28 4 German (search engine provider) English 29 Wir werden die Preise anziehen. put rise ok INCORRECT We will put the prices. 30 Boris Becker machte seinen wichtigsten Punkte beim Aufschlag. OK OK OK Boris Becker made his most important points when serving. 31 Nach diesern Fehlschlag musste er mit einer Anzeige rechnen. reckon/display count/ OK INCORRECT After this failure he had to denunciation reckon with a display. 32 Der Läufer ist ein Teppich dessen Länge viel gröBer lst, als die rotor rug ok INCORRECT The rotor is a carpet whose Breite. length is much greater than the width. 33 Im Zug der Feuerwehr waren mehrere Bekannte. train/fire march/ FALSCH INCORRECT In the train of the fire were fire brigade several acquaintances. 34 Der letzte Zug des Schachspielers war ein Fehler. train move ok INCORRECT The last train of the chess player was a mistake. 35 Vor dern Zug marschierte ein Fahnenträger. train procession — INCORRECT Before the train marched a standard-bearer.

TABLE 7 Standard terms and technical terms from linguistics and computational linguistics used in the explanation of the invention Word Brief definition ambiguous [Duden] ambiguous, double meaning; (French ambigu <) Latin ambiguus, to: ambigere: to doubt; be inconclusive ambiguity Something which is ambiguous antonym [Wiki de] Antonyms (from Greek - anti-‘against’ and ‘onoma’ ‘name’) in linguistics are words with opposite meaning. With equivalent meaning the German terms ‘Gegensatzwort’ (or briefly, Gegenwort) are also related. equivocation Dual meaning, ambiguity; frequently used as a synonym of homonymy data Components of information retrievable from hardware memories or signal currents, mostly materially and permanently recordable. [Cf. Also fundamental difference from“knowledge” . . . Knowledge U Data = Information] deictic, deixis Deictic references in linguistics are those which contain information e.g. on subjects which are agents in other sentences of a text. (in broad terms = link). Frequently this reference is only represented e.g. by a pronoun matching the acting subject or object. For example: “Mary is the new baker. She makes the tastiest rolls in the city.” In this case a deictic reference exists between “she” and “Mary”, or “baker”. It is also said that sentence 2 contains deixis. [Duden, Deixis = referential function of words (e.g. pronouns such as ‘this’, ‘that’ adverbs such as ‘here’, ‘today’) in a context] deterministic [Brockhaus] mandatorily determined by pre-specified conditions EDP Electronic data processing Inflection See base word gender [Canoo.net] category of nouns (and by formal agreement in the sentence also of adjectives, articles and pronouns). In German there are masculine, feminine and neuter nouns. graph-based relating to the structure of the relationships between entities, represented as a graph. Base word, base form The base form of a word is the uninflected form: from the plural ‘cars’ the basic form is ‘car’. From the conjugated form ‘going’ the basic form is ‘go’, etc. Words that are not in their base form, are referred to in broad terms as inflections or inflected. Homophone [Duden] Homophones = words which sound phonetically identical - or very similar - to others, but are spelled differently Homonym [Brockhaus] Homonyms = words which match in pronunciation and spelling . . . [Duden] have the same articulation . . . but a different meaning. In German, approximately 35,000 words with approximately 100,000 meanings (accordingly approximately 2 to 3 for each homonym). All high-level languages have an approximately equal proportion of homonyms. In all languages, approximately 80% of the 2000 most frequently used words are homonyms. Homonymy The fact that words are homonyms Hypernym [Brockhaus] Hyperonym, also hypernym = hierarchy of semantic ranking = More general meaning for a word) e.g. a hyperonym of “cigarette” is “smoking material” Hyponym Hyponym = more concrete, more specific, meaning for a word, e.g. a hyponym of cigarette is “roll-up” Interjection [Duden] syntactically often isolated, word-like utterance, used to express feelings or requests or to imitate sounds; calling word, feeling word (e.g. oh, huh, psst, um) intransitive Intransitive verbs have no direct object, or the object is the subject itself. I.e. the subject carries out a self-directed action. Many verbs allow both transitive and intransitive usage: e.g. “bake” allows both “I bake” (intransitive) and “I bake a cake” (transitive) Case [Canoo.net] Form of inflections of nouns, adjectives and pronouns. German has four cases: nominative, accusative, dative, genitive. Compound(s) [Duden] composite word; (Linguistics) compound. Occurs with nouns, adjectives, verbs, adverbs and pronouns Conjunction [Canoo.net] word which connects phrases or sentences together. Examples: and, or, because, during. Synonym: linking word Looks-like method Method for displaying the words in a text that have similar spelling to others, e.g. due to omitted letter characters, such as umlaut dots, accents, etc., or substitution of similar letters: i-l, y-y (gamma-y), β-β (ess-zet/beta), by similarly spelled words which occur in the text and which are known to be a word, e.g. in a database, to a user for checking or otherwise processing Human-machine dialog Dialogs that are computer-controlled and take place on a human- machine interface Modulation [Wiki de] The term modulation (from Lat. modulatio = beat, rhythm) in communications technology describes a process in which a useful signal to be transmitted (for example, music, speech, data) modifies (modulates) a so-called carrier. Monolingual Relating to only a single language; antonym: multilingual = relating to multiple languages High level natural language High level language also termed ‘standard’ language, literary language or written language, e.g. High German, Cambridge English, Castilian Spanish. In the narrower sense, any language with comprehensive, written grammatical rules, specified semantics and ontology. Neural networks [Wiki de] A neural network is the abstract structure of a nervous system or a model with such an information architecture Number [Duden] <Linguistics> grammatical category which indicates by means of inflected forms (in nouns, adjectives, articles, pronouns) the number of the objects or persons referred to or (in the case of verbs) that of the agents affected by an event. 2 other homonyms . . . OCR From English “Optical Character Recognition” Ontology [Duden] (Informatics) system of information with logical relations [Wiki de] (Informatics) ontologies in informatics are usually linguistically captured and formally structured representations of a set of definitions and the relations existing between them in a particular subject domain. They are used to exchange “knowledge” in a formal digitized form between applications programs and services. Knowledge here includes both general knowledge and knowledge about very specific subject areas and procedures. Ontologies contain inference and integrity rules, i.e. rules for drawing conclusions and for guaranteeing their validity. Ontologies have experienced an upturn in recent years with the idea of the semantic web and are therefore part of the knowledge representation in the sub-domain of artificial intelligence. In contrast to a taxonomy, which only forms a hierarchical sub-classification, an ontology represents a network of information with logical relations. In publications, often described as an “explicit formal specification of a . . . Parallel corpora Usually corpora for which a translation exists for each text, and which can be aligned Particle, sentence particle Particles refer to a class of function words. The particles - in a broad sense - are considered to include all non- inflecting words of a language. E.g. “die, der, das” in German can also be articles of different case or number, demonstrative pronouns or relative pronouns. “aus” in German can be a preposition (“aus der Mitte” = from the middle) or temporal adverb (“das Spiel ist aus” = the game is over). “zu” can be a preposition, conjunction or temporal adverb. multilingual See monolingual polysemy [Wiki de] Polysemous (from Greek polis, ‘many’ or ‘several’ and sema ‘sign/symbol’) designates in linguistics a linguistic symbol (e.g. word, morphem or syntagm) which stands for different meanings or definitions. The property of being polysemous is called polysemy. Polysemous words are not univocal. Polysemy differs from homonymy in particular in the differentiation of a common semantic relationship. Polysemy can lead to misunderstandings and false inferences, but can also be used in word play, creative language or in literary ways. Preposition [Canoo.net] Word that relates words and/or phrases to each other and reproduces a particular, e.g. spatial or temporal relationship. E.g. the boy climbs up (preposition) the tree. Sounds-like method Method for displaying to the user similarly spoken words occurring in the text and which are unknown as words e.g. to a database, using known similarly sounding words from the database, for checking, or for otherwise processing. Speech recognition [Wiki de] Speech recognition, or automatic speech recognition, is a sub-domain of applied informatics, engineering and computational linguistics. It deals with the investigation and development of methods which make spoken language available to automatic data acquisition by automata, in particular computers. Speech recognition is to be distinguished from voice or speaker recognition, a biometric method of person identification. The implementations of these methods are similar, however. Language-invariant Language related features that apply to all languages Synonym [Wiki de] Synonym (from Greek synonymos, consisting of syn ‘together’ and onoma ‘name’) is the term which describes different linguistic or lexical expressions or symbols which have the same or very similar semantic scope. In particular, different words with identical or similar meaning are synonyms of each other, they stand in the relation of synonymy or equivalence or similarity or relatedness of meaning, sense or usage. transitive Transitive = a subject-object relation exists in the sentence due to the verb in question; see also “intransitive” Univocity, univocality [Wiki it, translated] allowing no ambiguity, non- confusability . . . Often cited in 7 homonyms, depending on the discipline. Including: <Linguistics> univocality, fact of being univocal <Mathematics> the fact that an element of a group corresponds to a single element of another group Valency reference, valence [Wiki de] the technical term valence (value, significance) in linguistics means the property of a word to join other words to itself, to “require” endings or to create empty positions and to regulate their occupation”. The main agent in valence theory is the verb (verb valence). Valence is not only possessed by verbs, but also other types of word such as nouns (substantive valence), adjectives (adjective valence) and prepositions. World knowledge Normally intended to refer to generally known data from lexica, e.g. on historical names, known personalities, but also structured definitions of terms, natural laws etc. Knowledge A non-material component of information, which exists by associations of, data/perceptions with experience and imagination in the brain of living creatures, or may be retrieved, learned and/or generated by them Word morphology [Wiki de] The term morphology (from Greek morphe ‘form’ and logos ‘word’, ‘teaching’, ‘reason’), also known as morphematics or morphemics in understood in linguistics as a sub-domain of grammar. Morphology deals with internal structure of words and is dedicated to finding the smallest meaning-bearing and/or function-bearing elements of a language, the morphemes. Morphology is also known as “word grammar” by association with the term “sentence grammar” for syntax. 

1. A method for automatically detecting meaning-patterns in a text using a plurality of input words comprising a database system containing words of a language, a plurality of pre-defined categories of meaning in order to describe the properties of the words, and meaning-signals for all the words stored in the database, wherein a meaning-signal is an univocal numerical characterization of the meaning of the words using the categories of meaning, and wherein at least the following steps are carried out: a) reading of the text with input words into a device for data entry, linked to a device for data processing, b) comparison of all input words with the words in the database system that is connected directly and/or via remote data line to the system for data processing, c) assignment of at least one meaning-signal to each of the input words, wherein in the case of homonyms two or more meaning-signals are assigned; d) in the event that the assignment of the meaning-signals to the input words is univocal, the meaning-pattern identification is complete, e) in the event that more than one meaning-signal could be assigned to an input word, the relevant meaning-signals are compared with one another in an exclusively context-controlled manner, wherein f) on the basis of the combination of the meaning-signals of the input words among one another, it is determined whether a contradiction or a match is present in the meaning of the input word with respect to the context; g) meaning-signal combinations that lead to contradictions are rejected, meaning-signal combinations for matches are automatically numerically evaluated in accordance with the degree of matching of their meaning-signals based on a pre-defined matching criterion and recorded, h) automatic compilation of all input words resulting from the steps d) and g) are output as the meaning-pattern of the text.
 2. The method as claimed in claim 1, wherein, in accordance with the pre-defined matching criterion, it is automatically decided whether the meaning-pattern for at least one input word of the text has more than one remaining meaning, so that no unique meaning-pattern and/or no unique meaning of the sentence exists in the context and a display of the non-uniqueness and its cause is provided and/or made available to a User Interaction Manager if required.
 3. The method as claimed in claim 1, wherein, the text with the input words is a string of characters that originates from a written text and/or from any other source, including an acoustically recorded text using a speech recognition program, or photographed text, or OCR.
 4. The method as claimed in claim 1, wherein, a signal for the degree of univocality of a text which can be further processed is generated if following step e) of the claim, the remaining number of meaning-signals for all input words of a text is known.
 5. The method as claimed in claim 1, wherein, after a word meaning score “SW” and a sentence meaning score “SS” is calculated by a meaning modulator for all of the words of the text wherein the word meaning score is the number of entries of each word in the database system, coupled with the relevance of the meaning-pattern of each word in the context of the sentence: a) if the meaning score “SW” for a word of the sentence is equal to 0 (zero), then the word is spelt incorrectly and the sentence receives the sentence score “SS”=0, b) if the meaning score “SW” for a word of the sentence is greater than 1, then the analyzed sentence is incorrect, and/or not univocally formulated, because words with SW>1 have more than 1 possible meaning in the sentence and its context, wherein the sentence score is then set to “SS”=“SW”, c) if more than one word of the sentence have meaning score “SW”>1, then the sentence score “SS” is set to the maximum value “SW” of the meaning scores of the words of the respective sentence, d) if all the words of the sentence have a meaning score “SW”=1 then the sentence is univocal and receives the sentence score “SS”=1, e) if words have a meaning score “SW”=−2, then they allow both upper and lower case spelling, wherein the sentence score “SS” then receives the value “SS”=−2, until the correct upper or lower case spelling of the words with “SW”=−2, in this sentence, is finally calculated using further iterative steps, f) if the text originates from speech input and if words have a meaning score “SW” not equal to 1 and belong to a homophone group—identified from the data processing system—then they receive the meaning score “SW”=−3, and the sentence score “SS” retains the value −3 until the correct homophone of the group in this sentence and its context is finally calculated using further iterative steps, g) if words of the sentence have meaning score “SW”>1, then with words of an arbitrary number “v” of preceding or of “n” following sentences of the text it is checked whether words are included here which due to the modulation of their meaning-signals lead to “SW”=1 in the input sentence, wherein for normal speech applications and easily understandable texts, usually “v”=1 and “n”=0.
 6. The method as claimed in claim 5, wherein, with words with SW=0, a storable error message is generated, which in particular indicates spelling errors of all the words of the text and in particular the calculated possibilities for eliminating the error, and is stored sequentially in an error-message-storage and is available to a User Interaction Manager when required.
 7. The method as claimed in claim 4, wherein, with in words with “SW”=−2, a storable error message is launched, which in particular indicates the presence of case errors in the spelling of all the words of the sentence, naming the word position in the sentence, the cause of the error and displaying possibilities for eliminating the error calculated from the storage of the database system, and is stored sequentially in the error-message-storage and is available to a User Interaction Manager when required.
 8. The method as claimed in claim 1, wherein, in the event that no words have SW=0, a meaning modulator updates on a rolling basis the main theme—as the most frequent, valid constraint reference from in the form of its meaning-signal—of the current paragraph in the form of the meaning-signals of the constraint references and is made hierarchically retrievable and available to a User Interaction Manager when required.
 9. The method as claimed in claim 1, wherein, in the case of sentences with SS>1 an autotranslation message is generated, which lists the still existing #SW meaning possibilities of each word and in each case retrieves the most common synonyms of each word from the database system using its valid meaning-signals and stores them sequentially in the autotranslation storage and makes them available to a User Interaction Manager when required.
 10. The method as claimed in claim 1, wherein it is part of a computer-implemented translation device for the translation of texts, in particular sentences of a natural language into a target language, by using “meaning-checking”, wherein a sentence with score SS=1 is automatically acquired, or the text is processed until at least one sentence with sentence score=1 exists, and/or there are no unprocessed sentences left with SS unequal to
 1. 11. The method as claimed in claim 10, wherein the text is translated into the selected target language, taking into account the pre-defined, univocal meaning-signals of all words and all additional information that are available in the storages and Interaction Manager.
 12. The method as claimed in claim 10, further comprising an application of language-pair-specific rules of the database system, which by adjustment of the order of the words in the input sentence in relation to their morphology and inflection, and of the order of the sentence constituents, determines main clauses, dependent clauses, inserted dependent clauses, subjects, predicates, objects, text parts between hyphens, text parts between two brackets (open/closed), and places the sentence in memory in the target language in an order that is at least as semantically, morphologically, grammatically and syntactically as correct in the target language as in the input sentence, taking into account all sentence-related entries in memories.
 13. The method as claimed in claim 1, wherein the resulting words of the translation are displayed and/or acoustically reproduced, or represented on an output medium so that they are perceptible by other sensory organs.
 14. The method as claimed in claim 1, wherein in the presence of words with homophones in a sentence and appropriate specification, a review of the degree of meaning-signal correspondence of the present word and all its other homophonous spellings from database system in relation to the context is performed automatically, whereupon an automatic replacement by the homophone with the highest meaning modulation in the sentence takes place and/or an error message is output via error-message-storage and Interaction Manager if there is insufficient computational differentiation among the meaning-signals of the words of an identical homophone group in the context.
 15. The method as claimed in claim 1, wherein for processing and/or reconstructing garbled texts from automatic speech recognition of a natural language in the presence of background noise and/or text with typing errors, OCR, and subject to the condition that for at least one word SS=0, the possibilities for reformulating the sentence are automatically and systematically determined, by correctly spelling incorrect words, firstly with the priority on words that are similar to homophones of the relevant word, or that correspond to omissions of letters, spaces or typical typing errors when operating a keyboard, including upper/lower case, and accenting.
 16. The method as claimed in claim 15, wherein the meaning-signals of correctable words are used to investigate whether sentences with a sentence score SS=1 are produced which the user then receives as prioritized output, and/or the procedure is terminated if no usable hits can be identified after a user-specified time, wherein the input sentence is then tagged with the information of the words that were analyzed for correction, and if only sentences with a score unequal to 1 exist, those having the fewest words with SW=0 are prioritized for the tagging, wherein the overall result obtained is made available to a User Interaction Manager via error-message-storage and autotranslation storage.
 17. The method as claimed in claim 1, wherein for a search engine for searching in databases, the textual content of which are tagged by “meaning-checking” and can be queried automatically based on the automatic tagging.
 18. The method as claimed in claim 17, wherein an automatic database updating takes place in accordance with the meaning-signals of all of its words before the search process.
 19. The method as claimed in claim 1, wherein, an automatic inclusion of all same-language synonyms and all foreign-language synonyms in all their valid inflections is included in the search (same meaning-signal as the search term).
 20. The method as claimed in claim 1, wherein, when using multiple search words, a combination of the meaning-signal hits as claimed in the association logic of the search words is carried out.
 21. The method as claimed in claim 1, wherein, it performs a computer-implemented evaluation of the relevance of statements in the form of text in natural language to a topic specified in writing, by, in the case of an automatically acquired sentence with sentence score SS=1, the meaning-signals of the words of the sentence with pre-defined combinations or patterns of meaning-signals being automatically compared with tagged words of the comparison topic.
 22. The method as claimed in claim 21, wherein, the overlap of the meaning-signals of the topic specification and the input sentence with pre-defined meaning modulation patterns is ranked, taking into account the existence of meaning-signals of logical operators and/or disjunctors and/or other sentential connectors within the sentence structure of the input sentence.
 23. The method as claimed in claim 1, further comprising a computer-implemented conduct of automatic dialogs by computers and/or “responding computers” with users, so that the spoken input of a user is acquired as text by the responding computer and processed with “meaning-checking”.
 24. The method as claimed in claim 23, wherein, a breakdown of the input text into individual sentences is carried out by the responding computer, and an automatic evaluation is made as to which of these sentences are statement sentences, question sentences, or exclamation sentences.
 25. The method as claimed in claim 1, wherein the meaning-signals of the statement and question sentences of the user are compared based on their matching/correspondence with a tagged database of the statement sentences, response sentences and standard question sentences of a machine-readable text ontology of the responding/dialog-participating computer, which exists in the same natural language—but not necessarily—as the natural language in which the user interacts, wherein at least one of the following steps is carried out: (a) in the case of matching values of the meaning-signals of the input sentences of the user above a certain level, with the computer ontology of the responding computer, the response and statement sentences rated the highest in the matching/correspondence value are identified from the computer ontology being used, (b) the responding computer generates a structured, automatic response for the user by confirmation of the highest ranking sentences of the user in relation to the computer ontology by the responding computer via a speech output system in accordance with the state of art and/or other sensorially detectable transmission procedure, (c) offering the highest ranking response sentence of the computer ontology of the responding computer via a speech output system in accordance with the prior art and/or other sensorially detectable transmission procedure which only allows the user to make controlled answers on request, (d) sending of a link and/or sensorially detectable information by the responding computer—as claimed in certain rules of the ontology and appropriate to the meaning of the user's questions—which the user receives, in order to retrieve and/or read more detailed information on his questions and then to be able to put more targeted questions to the responding computer that the user himself might otherwise only have found in the computer ontology which is readable for him after some search effort of his own, (e) in the case of matching values of the meaning-signals below a certain matching level, a standard dialog based on its previous questions is called up in the responding computer, to which the user can only answer “Yes” or “No”, and/or by uttering controlled pre-defined, in particular spoken, alphanumeric, audible, sensible or visually perceptible options, and/or that an automatic detection is carried out in the responding computer of the moment from which the intervention of a human being is needed, by automatic evaluation of the redundancy of the dialog or of content-based patterns such as anger or impatience, of meaning-signal patterns in the verbal responses of the user during the dialog and/or visually perceivable responses of the user via a camera in the immediate environment of his data input device.
 26. The method as claimed in claim 1, further comprising a computer-implemented, enhanced spell-checking, by using “meaning-checking”, wherein in particular an automatic execution takes place but without the sentence itself being tagged with the meaning-signals after having reached a sentence score>0, equivalent to the fact that the text is only checked for spelling errors and corrected interactively by the user, but without necessarily any tagging of the sentence with e.g. semantic or logical additional information taking place.
 27. The method as claimed in claim 1, further comprising a computer-implemented word recognition during typing of words on keyboards by using “meaning-checking” and automatic completion of the words with words from the database system which best match the syntax and context existing at this point in time.
 28. A computer-implemented method for the semantic encryption of sentences of a natural language, using “meaning-checking” as claimed in claim 1, wherein, “m” words in each sentence are replaced in a grammatically/semantically well-formed manner, and/or “n” words are added in a grammatically/semantically well-formed manner, which have suitable meaning-signals compared to their immediate, contextual environment, which indicate that by insertion, negation, relativization or omission and/or by use of antonyms thereof from the database of the database system the sentence meaning can be changed significantly, but without the sentence score being changed, equivalent to the fact that, after the automatic modification, the text contains no additional semantically/factually less meaningful sentences than the original from which it is produced, with “m”>=1 or “n”>=0, and wherein at least one of the following steps is carried out: a) all alphanumeric chains which are proper names and/or dates and/or pure numbers which have their own meaning-signals, or to which automatically matching meaning-signals can be automatically assigned, and/or single words marked in advance are each replaced by coded, anonymized keywords, to which shortened meaning-signals, appropriate to the degree of anonymization, are automatically added, b) the user's starting sentences are stored on the user's system taking account of the original order, and a log file is stored of all changes that were created as sentence variants or anonymizations, wherein each change and derivable content of the change and the position in the respective sentence of the text are recorded, c) the user is assisted with “meaning-checking”, to identify from other retrievable text databases on the system he is using than the current text itself, sentences that are semantically—but not logically—similar to sentences from the input text to be encrypted, and that have a sentence score SS=1, d) the number of sentences of the original text is increased to at least 7 if over the input text plus sentence variants there are less than 7 sentences to be encrypted, e) a text is created which contains the user's starting sentences, plus “m” appended sentences which are automatically created variants of his, f) a stochastic scrambling of the sequence of the existing sentences is carried out and the explicit modification of the sequence before and after the scrambling is appended to a log file, g) if the unchanged, but scrambled text and the generated log files are available, the original text which the user originally entered, can be flawlessly reconstructed to match the original, h) potential system queries of the encrypted text are tagged on the individual words and sentences in such a way that, after reconstruction of the original text autotranslation queries, error messages and semantic information of the sentences can automatically cancel each other out, so that context-related information items which due to the scrambling are initially no longer in context, are reconstructed automatically in the original text, and without user interaction if this was not required in the unscrambled text. 